Advanced Search

dharr

Dr. David Harrington

8365 Reputation

22 Badges

21 years, 14 days
University of Victoria
Professor or university staff
Victoria, British Columbia, Canada

Social Networks and Content at Maplesoft.com

Maple Application Center
Contact Dr. David Harrington
I am a retired professor of chemistry at the University of Victoria, BC, Canada. My research areas are electrochemistry and surface science. I have been a user of Maple since about 1990.

MaplePrimes Activity


These are replies submitted by dharr

non-Schrodinger...

dharr 8365
21 hours ago
0 0

@salim-barzani 

non-schrodinger.mw

Comments...

dharr 8365
Yesterday at 11:09 AM
0 0

@salim-barzani Converting abs to conjugate immediately doesn't always solve the problem of diff with abs, but adding the Physics package usually solves this problem.

For the substitution u(x,t) =f(x,t)*exp(I*g(x,t)), it makes sense to me that one would choose f(x,t) and g(x,t) real since then they are simply interpreted as amplitude and phase functions, and subsequent math using real functions is simpler. Since Eq 11 in the original paper in this thread has no conjugate(theta), I think those authors chose theta real.
In the last paper f(x,t) was allowed to be complex and so the equivalent of Eq 11 had complex conjugates. However then the phase is not simply g(x,t) which leads to difficulties in interpretation. Bottom line, you can do it either way.

Edit:

If one just assumes Q(x,t) is real, then one finds that m is always real, which makes sense since it is part of the phase under the assumption f(x,t) and g(x,t) are real:

p5.mw

Perhaps there is some subtle physics reason to have a complex amplitude function. But looks like different papers make different choices.

complex Q...

dharr 8365
Yesterday at 6:49 PM
0 0

@salim-barzani Yes, I assumed Q(x,t) was real. Rather than the awkward hand-coding of abs(u(x,t)) as U, it is easier just to enter the abs as written, then use convert(.., conjugate). So here is this case, which comes out correctly. [Edit, p4 slightly more general than earlier p3]

restart

with(PDEtools); with(LinearAlgebra); with(Physics, diff)

undeclare(prime, quiet)

declare(u(x, t), quiet); declare(Q(x, t), quiet)

pde := convert(I*(diff(u(x, t), t))+diff(u(x, t), `$`(x, 2))+abs(u(x, t))^2*u(x, t), conjugate)

I*(diff(u(x, t), t))+diff(diff(u(x, t), x), x)+u(x, t)^2*conjugate(u(x, t))

T := u(x, t) = (sqrt(a)+Q(x, t))*exp(I*a*t)

u(x, t) = (a^(1/2)+Q(x, t))*exp(I*a*t)

pde2 := `assuming`([eval(pde, T)], [a::positive, x::real, t::real])

I*((diff(Q(x, t), t))*exp(I*a*t)+I*(a^(1/2)+Q(x, t))*a*exp(I*a*t))+(diff(diff(Q(x, t), x), x))*exp(I*a*t)+(a^(1/2)+Q(x, t))^2*(exp(I*a*t))^2*exp(-I*a*t)*(a^(1/2)+conjugate(Q(x, t)))

E := expand(simplify(collect(pde2/exp(I*a*t), exp), exp))

Q(x, t)*a+a*conjugate(Q(x, t))+2*a^(1/2)*conjugate(Q(x, t))*Q(x, t)+a^(1/2)*Q(x, t)^2+conjugate(Q(x, t))*Q(x, t)^2+I*(diff(Q(x, t), t))+diff(diff(Q(x, t), x), x)

This needs to be linearized with respect to Q. Just throw away second and higher order terms in Q/conjugateQ. We can't use coeff on Q(x,t), so will do it in jet notation.

PJ := ToJet(E, Q(x, t), jetnotation = jetvariableswithbrackets); Q_vars := select(has, indets(%), Q); P2 := FromJet(remove(proc (q) options operator, arrow; 1 < degree(q, Q_vars) end proc, PJ), Q(x, t))

{Q[], Q[t], Q[x, x], conjugate(Q[])}

Q(x, t)*a+a*conjugate(Q(x, t))+I*(diff(Q(x, t), t))+diff(diff(Q(x, t), x), x)

We assume theta has the form

TT := Q(x, t) = r[1]*exp(I*(l*x-m*t))+r[2]*exp(-I*(l*x-m*t))

Q(x, t) = r[1]*exp(I*(l*x-m*t))+r[2]*exp(-I*(l*x-m*t))

We substitute this in P2 and collect the coefficients of the two exp terms

P3 := `assuming`([eval(P2, TT)], [real])

(r[1]*exp(I*(l*x-m*t))+r[2]*exp(-I*(l*x-m*t)))*a+a*(r[1]*exp(-I*(l*x-m*t))+r[2]*exp(I*(l*x-m*t)))+I*(-I*r[1]*m*exp(I*(l*x-m*t))+I*r[2]*m*exp(-I*(l*x-m*t)))-r[1]*l^2*exp(I*(l*x-m*t))-r[2]*l^2*exp(-I*(l*x-m*t))

P4 := collect(P3, exp); indets(%)

(-l^2*r[2]+a*r[1]+a*r[2]-m*r[2])*exp(-I*(l*x-m*t))+(-l^2*r[1]+a*r[1]+a*r[2]+m*r[1])*exp(I*(l*x-m*t))

{a, l, m, t, x, r[1], r[2], exp(-I*(l*x-m*t)), exp(I*(l*x-m*t))}

subs({exp(-I*(l*x-m*t)) = X, exp(I*(l*x-m*t)) = Y}, P4); eqs := [coeff(%, X), coeff(%, Y)]

[-l^2*r[2]+a*r[1]+a*r[2]-m*r[2], -l^2*r[1]+a*r[1]+a*r[2]+m*r[1]]

Set up these as matrix equations in the unknowns alpha[1] and alpha[2]

M, b := GenerateMatrix(eqs, [r[1], r[2]])

Matrix(%id = 36893490112467605252), Vector[column](%id = 36893490112467605132)

There is a nontrivial solution to these equations iff the determinant is zero. The determinant is a quadratic in m.

detM := Determinant(M)

-l^4+2*a*l^2+m^2

And we solve for w to define the dispersion relationship. T

ans := sort([solve(detM, m)])

[(l^2-2*a)^(1/2)*l, -(l^2-2*a)^(1/2)*l]

m is real when the expression under the square root is positive

ans[1]

(l^2-2*a)^(1/2)*l

Since detM is a quadratic, we can just find the discriminant.

expand(discrim(detM, m)/(4*l^2))

l^2-2*a

NULL

Download p4.mw

take-home mesaage?...

dharr 8365
September 02 2025
0 0

@acer Thanks for that improvement. (I played around with this at various times, and thought I'd tried that and found it inferior, but I must have misremembered.). I expected that _d01amc would be the default for a semi-infinite range, but infolevel suggests the range was split into 2 and the part from 15 to infinity done by a non-NAG routine.

I guess the take-home message is that if you are about to do a plot with thousands of integrations, choose a specific NAG one (after testing it against the slower default) so that the overhead of the singularity analysis etc is not done thousands of times.

Fast and accurate...

dharr 8365
September 01 2025
0 0

@Paras31 Here's an analysis that shows how to get both fast and accurate results from the Fokas method.

restart;

Maple's solution as per Rouben's answer - we'll use this as the benchmark

rsol:=1/2/Pi^(1/2)*(1/4*x*Int(sin(t-zeta)/zeta^(7/2)*exp(-1/4*x^2/zeta)*(x^2
-6*zeta),zeta = 0 .. t)+Pi^(1/2)*(erf(1/2*(2*t+x)/t^(1/2))*exp(x+t)-erf(1/2*(2*
t-x)/t^(1/2))*exp(-x+t)-exp(x+t)+exp(-x+t)));

(1/2)*((1/4)*x*(Int(sin(t-zeta)*exp(-(1/4)*x^2/zeta)*(x^2-6*zeta)/zeta^(7/2), zeta = 0 .. t))+Pi^(1/2)*(erf((1/2)*(2*t+x)/t^(1/2))*exp(x+t)-erf((1/2)*(2*t-x)/t^(1/2))*exp(-x+t)-exp(x+t)+exp(-x+t)))/Pi^(1/2)

Take a sample (x,t) for testing the different approaches.

params := {x = 0.5, t = 0.1};

{t = .1, x = .5}

ans_exact := evalf(eval(rsol, params));

.6581132195

As part of the Fokas method we need to evaluate an integral - set up its integrand. Here I use expressions rather than nested functions for a little more efficiency

V := -1/2*I*exp(k*x*I - k^2*t)*(1/(k - I) + 1/(k + I) - k*(1/(k^2 + I) + 1/(k^2 - I)))/Pi:
k1 := r*exp(1/8*I*Pi):
k2 := r*exp(7/8*I*Pi):
dk1 := exp(1/8*I*Pi):
dk2 := exp(7/8*I*Pi):
integrand1 := eval(V, k = k1)*dk1 - eval(V, k = k2)*dk2;

-((1/2)*I)*exp(I*r*exp(((1/8)*I)*Pi)*x-r^2*(exp(((1/8)*I)*Pi))^2*t)*(1/(r*exp(((1/8)*I)*Pi)-I)+1/(r*exp(((1/8)*I)*Pi)+I)-r*exp(((1/8)*I)*Pi)*(1/(r^2*(exp(((1/8)*I)*Pi))^2+I)+1/(r^2*(exp(((1/8)*I)*Pi))^2-I)))*exp(((1/8)*I)*Pi)/Pi+((1/2)*I)*exp(I*r*exp(((7/8)*I)*Pi)*x-r^2*(exp(((7/8)*I)*Pi))^2*t)*(1/(r*exp(((7/8)*I)*Pi)-I)+1/(r*exp(((7/8)*I)*Pi)+I)-r*exp(((7/8)*I)*Pi)*(1/(r^2*(exp(((7/8)*I)*Pi))^2+I)+1/(r^2*(exp(((7/8)*I)*Pi))^2-I)))*exp(((7/8)*I)*Pi)/Pi

Numeric evaluation of this integral is very slow - 10 minutes!
But after adding the extra expression required by the Fokas method, it does give the correct answer

Fokas_int1 := CodeTools:-Usage(evalf(Int(eval(integrand1, params), r = 0 .. infinity)));
Fokas1 := evalf(eval(exp(-x/sqrt(2))*cos(t - x/sqrt(2)), params))+Fokas_int1;
ans_exact;

memory used=168.99GiB, alloc change=140.30MiB, cpu time=10.48m, real time=8.88m, gc time=2.50m

-0.2162433743e-1+0.*I

.6581132200+0.*I

.6581132195

The integrand is not explicitly real, but since it should be real, the OP (and the Mathematica code) evaluated the integral of the real part.
For this set of parameters (and default settings), we get an incorrect result, so this is not a good strategy.

Fokas_int2 := CodeTools:-Usage(evalf(Int(eval(Re(integrand1), params), r = 0 .. infinity)));

memory used=1.19GiB, alloc change=-5.91MiB, cpu time=8.14s, real time=7.23s, gc time=1.47s

Float(infinity)

Since the integrand is real, it makes sense to convert it into an explicitly real form

integrand2 := simplify(evalc(integrand1));

r*(((r^8-2*r^4+1)*2^(1/2)-2*r^6-2*r^2)*cos((1/2)*(r*t*2^(1/2)-2*cos((1/8)*Pi)*x)*r)+sin((1/2)*(r*t*2^(1/2)-2*cos((1/8)*Pi)*x)*r)*(r^8*2^(1/2)+2*r^6-2*r^2-2^(1/2)))*exp(-(1/2)*(r*t*2^(1/2)+2*cos((3/8)*Pi)*x)*r)/((r^8+1)*(1+r^4+r^2*2^(1/2))*Pi)

This is much faster and gives the correct result.

Fokas_int2 := CodeTools:-Usage(evalf(Int(eval(integrand2, params), r = 0 .. infinity)));
Fokas2 := evalf(eval(exp(-x/sqrt(2))*cos(t - x/sqrt(2)), params)) + Fokas_int2;
ans_exact;

memory used=184.17MiB, alloc change=0 bytes, cpu time=953.00ms, real time=837.00ms, gc time=171.88ms

-0.2162433743e-1

.6581132200

.6581132195

However, it is still slow enough that it takes a very long time to do a 3D plot at different (x,t) with grid = [40,40] or even a 2D plot vs x for a fixed t with the default number of points and adaptive plotting.

So we seek to make it faster. The integrand is oscillating, and there is a NAG method _d01akc for oscillating integrals but it is not for an infnite range.
So we make a change of variables to a finite range.
Look at the asymptotic behaviour, whch is dominated by exp(-r^2*t/sqrt(2)).

asympt(integrand2, r);

O(1/r^3)*exp(-(1/2)*2^(1/2)*r^2*t)/exp(cos((3/8)*Pi)*r*x)

Suggesting the following change of variables to u ranging from 0 to 1

itr := u = 1 - exp(-r^2*t/sqrt(2));
eval(itr,r=0), eval(itr,r=infinity) assuming t>0;
tr := r = solve(itr, r)[1];

u = 1-exp(-(1/2)*2^(1/2)*r^2*t)

u = 0, u = 1

r = (-t*2^(1/2)*ln(-u+1))^(1/2)/t

int3 := PDEtools:-dchange(tr,Int(integrand2, r = 0..infinity), [u], simplify) assuming t>0;

t*(Int(((t^2+4*t*ln(-u+1)+2*ln(-u+1)^2)*cos((-ln(-u+1))^(1/2)*2^(1/4)*(-(1/2)*2^(3/4)*(-ln(-u+1))^(1/2)*t^(1/2)+cos((1/8)*Pi)*x)/t^(1/2))+sin((-ln(-u+1))^(1/2)*2^(1/4)*(-(1/2)*2^(3/4)*(-ln(-u+1))^(1/2)*t^(1/2)+cos((1/8)*Pi)*x)/t^(1/2))*(t^2-2*ln(-u+1)^2))*exp(-2^(1/4)*(-ln(-u+1))^(1/2)*cos((3/8)*Pi)*x/t^(1/2))/(4*ln(-u+1)^4+t^4), u = 0 .. 1))/Pi

integrand3 := IntegrationTools:-GetIntegrand(int3):
Fokas_int3 := t/Pi*Int(integrand3, u = 0..1, method = _d01akc):

It is indeed faster.

CodeTools:-Usage(evalf(eval(Fokas_int3, params)));

memory used=149.23KiB, alloc change=0 bytes, cpu time=16.00ms, real time=12.00ms, gc time=0ns

-0.2162433742e-1

We combine it with the rest to make a final procedure

approx_u := unapply(exp(-x/sqrt(2))*cos(t - x/sqrt(2)) + t/Pi*Int(integrand3, u = 0..1, method = _d01akc), x,t, numeric):

evalf(approx_u(0.5,0.1));

.6581132200

CodeTools:-Usage(plot3d(approx_u, 0 .. 3, 0 .. 2*Pi, grid = [40, 40], axes = boxed, labels = ["x", "t", "u(x,t)"], title = "Fokas Method of solution of Half-Line Heat Equation", shading = zhue));

memory used=272.54MiB, alloc change=0 bytes, cpu time=9.33s, real time=9.13s, gc time=437.50ms

p1 := plot(x -> approx_u(x, 0.1), 0 .. 2, color = red):
p2 := plot(x -> approx_u(x, 0.2), 0 .. 2, color = green):
p3 := plot(x -> approx_u(x, 0.3), 0 .. 2, color = blue):
p4 := plot(x -> approx_u(x, 0.4), 0 .. 2, color = magenta):
p5 := plot(x -> approx_u(x, 0.5), 0 .. 2, color = RGB(1.0, 0.5, 0.)):
p6 := plot(x -> approx_u(x, 0.6), 0 .. 2, color = cyan):
p0 := plot(exp(-x), x = 0 .. 2, linestyle = dash, color = black):
plots:-display([p0, p1, p2, p3, p4, p5, p6], legend = ["u(x,0)", "t=0.1", "t=0.2", "t=0.3", "t=0.4", "t=0.5", "t=0.6"], legendstyle = [location = right, font = [Helvetica, 12]], view = [0 .. 2, 0 .. 1.2], labels = ["x", "u(x,t)"], labelfont = [Helvetica, 12], axes = boxed, title = "Short-Time Behavior of u(x,t)");

NULL

Download Fokas.mw

another comment...

dharr 8365
August 29 2025
0 0

@dharr "and about step one is not about appearing twice i think, is about non linear term which we chose which a-N is bigger and non linear term is about a+b-N which N is begger and have same a then we can find b like the non couple equation ."

Let me see if I understand this. Say some terms give a-3, a-4, a-5 then we take the minimum a-5. Now suppose we have also a+b-3, a+b-4, a+b-5 so we take a+b-5. So now we set them equal and find b=0. Then the value a-5 and a+0-5 appears twice (since we set them equal). If we have different N, then we get different b (for the same a), e.g.,

a-6 = a+b-5 leads to b=-1, and then the value a-6 = a-1-5 appears twice.

Is there a problem with this?

comments...

dharr 8365
August 28 2025
0 0

@salim-barzani You say "intrested about the u[0],v[0] i think they are not the same which i am not sure which is corect  i don't have issue with yours one of g[x] is extra if you watch you will see". I don't see an extra g[x]; please specify exactly where this is (there are some g's there because I am not not calculating u[0] directly; do I have them incorrect?).

" the other point is about that condition how he got that condition in eq((16),  and when N=2 we have to find the u[1],u[2],..u[6] and v[1],v[2],...v[6] ". I don't see N=2 in eq 16. Please specify exactly where you mean.

You have now added the other paper here which I didn't deal with. That paper has p =1 and not p=-1 so that seems wrong to me. 

Basically I am not understanding; please spend a bit more time specifying some details of what you think is wrong or needs to be done. 

 

incremental solution...

dharr 8365
August 27 2025
0 0

@salim-barzani To get the resonances and other solutions correct you have to evaluate with the earlier solutions (see how I did the KdV example), and the resonant ones set to zero (not sure why, but otherwise their deriatives don't disappear). 

all-steps-Dr.D.mw

I am working to understand the coupled case.

Updates...

dharr 8365
August 27 2025
0 0

@salim-barzani I have updated the files here to reflect my improved understanding of the step 1 procedure. In particular see the plot in AllStepsHBnew.mw for how to interpret the lowest exponents rule. I'll work on the coupled case next.

Step 1 details...

dharr 8365
August 26 2025
0 0

@salim-barzani This paper doi.org/10.2991/jnmp.2006.13.1.8 seems clearer about how to do step 1, so I'll work through it; it also should help with the case of multiple equations as in the non-linear Schroedinger equations.

expression...

dharr 8365
August 26 2025
1 0

@acer's routine (and my general practice) expects the pde to be an expression, but you have added =0.

schrodinger-test.mw

algebraic and trig...

dharr 8365
August 26 2025
0 0

@Alfred_F So in general cos/sin/exp of an algebraic number is transendental. The only thing I know about the exceptions is that Maple sometimes finds roots of a polynomial in trig form, when they might (or might not?) be also be expressible in radical form. The case of cyclotomic polynomials where these are roots of unity is the easiest to find.

restart

p := x^6-x^5+x^4-x^3+x^2-x+1

x^6-x^5+x^4-x^3+x^2-x+1

sol := [solve(p, x)]

[cos((1/7)*Pi)+I*sin((1/7)*Pi), cos((3/7)*Pi)+I*sin((3/7)*Pi), -cos((2/7)*Pi)+I*sin((2/7)*Pi), -cos((2/7)*Pi)-I*sin((2/7)*Pi), cos((3/7)*Pi)-I*sin((3/7)*Pi), cos((1/7)*Pi)-I*sin((1/7)*Pi)]

rads := `~`[convert](sol, compose, exp, radical)

[1, (-1)^(2/7), (-1)^(4/7), (-1)^(6/7), -(-1)^(1/7), -(-1)^(3/7), -(-1)^(5/7)]

`~`[evalc](rads)

[1, cos((2/7)*Pi)+I*sin((2/7)*Pi), -cos((3/7)*Pi)+I*sin((3/7)*Pi), -cos((1/7)*Pi)+I*sin((1/7)*Pi), -cos((1/7)*Pi)-I*sin((1/7)*Pi), -cos((3/7)*Pi)-I*sin((3/7)*Pi), cos((2/7)*Pi)-I*sin((2/7)*Pi)]

``

Download trig.mw

remarks...

dharr 8365
August 24 2025
0 0

@salim-barzani You're wecome. I think you can get the extra functions for the HB (and other equations) by continuing solving the equations in turn, recognizing the resonant point ones will simplify to zero, after substituting in the earlier solutions (which shows the compatibility condition is satisfied, if I understand it correctly).

Sort was improved in 2025, but nothing much relevant to differential equations, so there is probably not much need for you to upgrade to 2025.

All steps for KdV and HB...

dharr 8365
August 24 2025
0 0

@dharr 

Here it is, so I think I am done!

AllStepsKdVnew2.mw

AllStepsHBnew.mw

update...

dharr 8365
August 24 2025
0 0

@salim-barzani I updated the solution to include step 3. It works for the Burgers equation, and it is clear that you have to think about the resonance points, and won't be able to just solve the whole system.

1 2 3 4 5 6 7 Last Page 1 of 87