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Scattering of weakly nonlinear dispersive wave ona parametric resonance
Oleg Kiselev ok@ufanet.ruInstitute of Mathematics, Ufa, Russia
collaborated with
S.Glebov, USPTU N. Tarkhanov, Potsdam University
Nonlinear Physics. Theory and Experiment. V, June, 12-20,2008
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Outlines
1 Parametric driven nonlinear Klein-Gordon equation
2 Small amplitude solution
3 Problem of control for weak nonlinear wave
4 Simulations
5 Asymptotic approach outside of resonance
6 Primary local parametric resonance
7 Scattering problem for the primary local resonance equation
8 Matching and connection formula for solution before and afterthe resonance
9 Conclutions
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Outlines
1 Parametric driven nonlinear Klein-Gordon equation
2 Small amplitude solution
3 Problem of control for weak nonlinear wave
4 Simulations
5 Asymptotic approach outside of resonance
6 Primary local parametric resonance
7 Scattering problem for the primary local resonance equation
8 Matching and connection formula for solution before and afterthe resonance
9 Conclutions
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Outlines
1 Parametric driven nonlinear Klein-Gordon equation
2 Small amplitude solution
3 Problem of control for weak nonlinear wave
4 Simulations
5 Asymptotic approach outside of resonance
6 Primary local parametric resonance
7 Scattering problem for the primary local resonance equation
8 Matching and connection formula for solution before and afterthe resonance
9 Conclutions
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Outlines
1 Parametric driven nonlinear Klein-Gordon equation
2 Small amplitude solution
3 Problem of control for weak nonlinear wave
4 Simulations
5 Asymptotic approach outside of resonance
6 Primary local parametric resonance
7 Scattering problem for the primary local resonance equation
8 Matching and connection formula for solution before and afterthe resonance
9 Conclutions
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Outlines
1 Parametric driven nonlinear Klein-Gordon equation
2 Small amplitude solution
3 Problem of control for weak nonlinear wave
4 Simulations
5 Asymptotic approach outside of resonance
6 Primary local parametric resonance
7 Scattering problem for the primary local resonance equation
8 Matching and connection formula for solution before and afterthe resonance
9 Conclutions
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Outlines
1 Parametric driven nonlinear Klein-Gordon equation
2 Small amplitude solution
3 Problem of control for weak nonlinear wave
4 Simulations
5 Asymptotic approach outside of resonance
6 Primary local parametric resonance
7 Scattering problem for the primary local resonance equation
8 Matching and connection formula for solution before and afterthe resonance
9 Conclutions
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Outlines
1 Parametric driven nonlinear Klein-Gordon equation
2 Small amplitude solution
3 Problem of control for weak nonlinear wave
4 Simulations
5 Asymptotic approach outside of resonance
6 Primary local parametric resonance
7 Scattering problem for the primary local resonance equation
8 Matching and connection formula for solution before and afterthe resonance
9 Conclutions
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Outlines
1 Parametric driven nonlinear Klein-Gordon equation
2 Small amplitude solution
3 Problem of control for weak nonlinear wave
4 Simulations
5 Asymptotic approach outside of resonance
6 Primary local parametric resonance
7 Scattering problem for the primary local resonance equation
8 Matching and connection formula for solution before and afterthe resonance
9 Conclutions
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Outlines
1 Parametric driven nonlinear Klein-Gordon equation
2 Small amplitude solution
3 Problem of control for weak nonlinear wave
4 Simulations
5 Asymptotic approach outside of resonance
6 Primary local parametric resonance
7 Scattering problem for the primary local resonance equation
8 Matching and connection formula for solution before and afterthe resonance
9 Conclutions
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Mathematical model
An object of this talk is solutions of parametric perturbednonlinear Klein-Gordon equation:
∂2t U − ∂2
xU +
(1 + εf cos
(S(ε2x , ε2t)
ε2
))U + γU3 = 0.
Here ε is small parameter, γ, f ∈ R and S(y , z) is smoothfunction.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Mathematical model
An object of this talk is solutions of parametric perturbednonlinear Klein-Gordon equation:
∂2t U − ∂2
xU +
(1 + εf cos
(S(ε2x , ε2t)
ε2
))U + γU3 = 0.
Here ε is small parameter, γ, f ∈ R and S(y , z) is smoothfunction.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Small amplitude solution
We study a small amplitude solution in the form of amodulated oscillating wave:
U(x , t, ε) ∼ εu1(x1, t1, x2, t2) exp{i(kx + ωt)}+ c .c ..
This solution depends on groups of scaled variables:
fast variables are x , t;slow variables are x1 = εx , t1 = εt;very slow variables are x2 = ε2x and t2 = ε2t.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Small amplitude solution
We study a small amplitude solution in the form of amodulated oscillating wave:
U(x , t, ε) ∼ εu1(x1, t1, x2, t2) exp{i(kx + ωt)}+ c .c ..
This solution depends on groups of scaled variables:
fast variables are x , t;slow variables are x1 = εx , t1 = εt;very slow variables are x2 = ε2x and t2 = ε2t.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Problem
Background
In a general approach the shape of the weak nonlinear wave isdefined by Nonlinear Schrodinger equation.There exist resonant curves on the plane (x2, t2) such that thisapproach is not valid near these curves and the main role playsthe perturbation.
Goals
To control of weak nonlinear dispersive waves.To find a connection formula for the solution before and afterthe resonance.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Problem
Background
In a general approach the shape of the weak nonlinear wave isdefined by Nonlinear Schrodinger equation.There exist resonant curves on the plane (x2, t2) such that thisapproach is not valid near these curves and the main role playsthe perturbation.
Goals
To control of weak nonlinear dispersive waves.To find a connection formula for the solution before and afterthe resonance.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Simulations
Annihilation of NLSE soliton
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Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Simulations
Generation of NLSE soliton
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Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Bounds of NLSE approach
It is well-known that the weak nonlinear waves are defined byNLSE.
Bibliography
P. L. Kelley, 15 (1965), pp. 1005-1008.
V. I. Talanov, ZhETF Letters, 1965, n2, pp. 218-222.
V. E. Zaharov, J Appl Mech. and Tech. Phys. 1968, n2, pp.86-94.
Further we show the borders of this approach for solutions of theparametric driven equation.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Theorem about external expansion
The asymptotic solution of PNGKE has the form
U = ε(u1(t1, x1, x2, t2) exp{i(kx2 + ωt2)/ε
2}+ c .c .)+
ε2(u+
2 exp(iφ+(x2, t2)/ε2) + u−2 exp(iφ−(x2, t2))/ε
2) +
c .c .)
+ . . . .
where
u1 = Ψexp
{−i
f 2
4ω
∫ t2[
1
L[φ−]+
1
L[φ+]
]dt2
}.
Function Ψ is determined by the NLSE:
iω∂t2Ψ− ∂2ζ Ψ + 3γ|Ψ|2Ψ = 0, ζ = ωx1 + kt1.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Theorem about external expansion
The asymptotic solution of PNGKE has the form
U = ε(u1(t1, x1, x2, t2) exp{i(kx2 + ωt2)/ε
2}+ c .c .)+
ε2(u+
2 exp(iφ+(x2, t2)/ε2) + u−2 exp(iφ−(x2, t2))/ε
2) +
c .c .)
+ . . . .
where
u1 = Ψexp
{−i
f 2
4ω
∫ t2[
1
L[φ−]+
1
L[φ+]
]dt2
}.
Function Ψ is determined by the NLSE:
iω∂t2Ψ− ∂2ζ Ψ + 3γ|Ψ|2Ψ = 0, ζ = ωx1 + kt1.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Theorem about external expansion
The asymptotic solution of PNGKE has the form
U = ε(u1(t1, x1, x2, t2) exp{i(kx2 + ωt2)/ε
2}+ c .c .)+
ε2(u+
2 exp(iφ+(x2, t2)/ε2) + u−2 exp(iφ−(x2, t2))/ε
2) +
c .c .)
+ . . . .
where
u1 = Ψexp
{−i
f 2
4ω
∫ t2[
1
L[φ−]+
1
L[φ+]
]dt2
}.
Function Ψ is determined by the NLSE:
iω∂t2Ψ− ∂2ζ Ψ + 3γ|Ψ|2Ψ = 0, ζ = ωx1 + kt1.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Theorem about external expansion
The correction term is defined by following formulas:
u±2 = − u1f
2L[φ±].
Here φ± is a phase function and L[ψ] is an eikonal operator
φ± = kx2 + ωt2 ± S(x2, t2), L[φ] ≡ −(∂t2φ
)2+
(∂x2φ
)2+ 1.
The expansion is valid in the domains
−ε−1
(− (∂t2φ±)2 + (∂x2φ±)2 + 1
)� 1,
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Theorem about external expansion
The correction term is defined by following formulas:
u±2 = − u1f
2L[φ±].
Here φ± is a phase function and L[ψ] is an eikonal operator
φ± = kx2 + ωt2 ± S(x2, t2), L[φ] ≡ −(∂t2φ
)2+
(∂x2φ
)2+ 1.
The expansion is valid in the domains
−ε−1
(− (∂t2φ±)2 + (∂x2φ±)2 + 1
)� 1,
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Theorem about external expansion
The correction term is defined by following formulas:
u±2 = − u1f
2L[φ±].
Here φ± is a phase function and L[ψ] is an eikonal operator
φ± = kx2 + ωt2 ± S(x2, t2), L[φ] ≡ −(∂t2φ
)2+
(∂x2φ
)2+ 1.
The expansion is valid in the domains
−ε−1
(− (∂t2φ±)2 + (∂x2φ±)2 + 1
)� 1,
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Local parametric resonance
The condition of primary local parametric resonance is anequation:
−(∂t2(kx2+ωt2±S(x2, t2))
)2+
(∂x2(kx2+ωt2±S(x2, t2))
)2+1 = 0
A typical local resonance generates new harmonics (seeGlebov, Kiselev, Lazarev, 2006) with
k1 = k ± ∂x2S |L[χ1,±1]=0, as |k1| 6= k
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Local parametric resonance
The condition of primary local parametric resonance is anequation:
−(∂t2(kx2+ωt2±S(x2, t2))
)2+
(∂x2(kx2+ωt2±S(x2, t2))
)2+1 = 0
A typical local resonance generates new harmonics (seeGlebov, Kiselev, Lazarev, 2006) with
k1 = k ± ∂x2S |L[χ1,±1]=0, as |k1| 6= k
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Bibliography
Firstly the local resonance was studied since of 1970’s:
J. Kevorkian, SIAM J. Appl. Math., 20 (1971), pp. 364-373.L. Rubenfeld, Stud. Appl. Math., 57 (1977), pp. 77-92.J. C. Neu, SIAM J. Appl. Math., 43 (1983), pp. 141-156.L. A. Kalyakin, Mathematical notes, 44 (1988),pp. 697-699.S. G. Glebov, Differential equations., 31 (1995),pp. 1402-1408.
The local resonance may be used for soliton generation andcontrol:
S.G. Glebov, O.M. Kiselev, V.A. Lazarev, Proceedings of theSteklov Institute of Mathematics. Suppl., 2003, 1, S84-S90.S.G.Glebov, O.M. Kiselev, V.A. Lazarev, SIAM J. Appl.Math., 2005, vol.65, n6, pp.2158-2177.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Bibliography
Firstly the local resonance was studied since of 1970’s:
J. Kevorkian, SIAM J. Appl. Math., 20 (1971), pp. 364-373.L. Rubenfeld, Stud. Appl. Math., 57 (1977), pp. 77-92.J. C. Neu, SIAM J. Appl. Math., 43 (1983), pp. 141-156.L. A. Kalyakin, Mathematical notes, 44 (1988),pp. 697-699.S. G. Glebov, Differential equations., 31 (1995),pp. 1402-1408.
The local resonance may be used for soliton generation andcontrol:
S.G. Glebov, O.M. Kiselev, V.A. Lazarev, Proceedings of theSteklov Institute of Mathematics. Suppl., 2003, 1, S84-S90.S.G.Glebov, O.M. Kiselev, V.A. Lazarev, SIAM J. Appl.Math., 2005, vol.65, n6, pp.2158-2177.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Local parametric resonance
Here we consider a special case which is called by localparametric resonance
k − ∂x2S = −k.
In this case new harmonics are not generated in theleading-order term but the envelope function changes.
The local parametric resonance was studied for ordinarydifferential equations by
Bibliography
V.S. Buslaev, L.A.Dmitrieva. Theor. Math. Phys., 1987, v.73,n3, pp.430-441.S.H. Oueini, C.-M. Chin and A.H. Nayfeh J. Of Vibration andcontrol 2000, 6, pp.1115-1133.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Local parametric resonance
Here we consider a special case which is called by localparametric resonance
k − ∂x2S = −k.
In this case new harmonics are not generated in theleading-order term but the envelope function changes.The local parametric resonance was studied for ordinarydifferential equations by
Bibliography
V.S. Buslaev, L.A.Dmitrieva. Theor. Math. Phys., 1987, v.73,n3, pp.430-441.S.H. Oueini, C.-M. Chin and A.H. Nayfeh J. Of Vibration andcontrol 2000, 6, pp.1115-1133.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Local parametric resonance
In a neighborhood of the parametric resonant curve the formalasymptotic expansion is
U(x , t, ε) = ε(w1(x1, t1, x2, t2) exp(iS(x2, t2)/ε) + c .c .
)+
ε2(w2,1 exp(iS(x2, t2)/ε)+w2,2 exp(2iS(x2, t2)/ε)+ c .c .
)+ . . . .
where w1(x1, t1, x2, t2) is a solution of
Local Parametric Resonance Equation
i∂x2S∂x1w1 − i∂t2S∂t1w1 + λw1 + f2w1 = 0.
and λ is a function which depends on slow and very slowvariables:
λ(x1, t1, x2, t2) = ε−1(−
(∂t2φ±
)2+
(∂x2φ±
)2+ 1
)
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Local parametric resonance
In a neighborhood of the parametric resonant curve the formalasymptotic expansion is
U(x , t, ε) = ε(w1(x1, t1, x2, t2) exp(iS(x2, t2)/ε) + c .c .
)+
ε2(w2,1 exp(iS(x2, t2)/ε)+w2,2 exp(2iS(x2, t2)/ε)+ c .c .
)+ . . . .
where w1(x1, t1, x2, t2) is a solution of
Local Parametric Resonance Equation
i∂x2S∂x1w1 − i∂t2S∂t1w1 + λw1 + f2w1 = 0.
and λ is a function which depends on slow and very slowvariables:
λ(x1, t1, x2, t2) = ε−1(−
(∂t2φ±
)2+
(∂x2φ±
)2+ 1
)
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Local parametric resonance
In a neighborhood of the parametric resonant curve the formalasymptotic expansion is
U(x , t, ε) = ε(w1(x1, t1, x2, t2) exp(iS(x2, t2)/ε) + c .c .
)+
ε2(w2,1 exp(iS(x2, t2)/ε)+w2,2 exp(2iS(x2, t2)/ε)+ c .c .
)+ . . . .
where w1(x1, t1, x2, t2) is a solution of
Local Parametric Resonance Equation
i∂x2S∂x1w1 − i∂t2S∂t1w1 + λw1 + f2w1 = 0.
and λ is a function which depends on slow and very slowvariables:
λ(x1, t1, x2, t2) = ε−1(−
(∂t2φ±
)2+
(∂x2φ±
)2+ 1
)Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Local parametric resonance
In a neighborhood of the parametric resonant curve the formalasymptotic expansion is
U(x , t, ε) = ε(w1(x1, t1, x2, t2) exp(iS(x2, t2)/ε) + c .c .
)+
ε2(w2,1 exp(iS(x2, t2)/ε)+w2,2 exp(2iS(x2, t2)/ε)+ c .c .
)+ . . . .
where w1(x1, t1, x2, t2) is a solution of
Local Parametric Resonance Equation
i∂x2S∂x1w1 − i∂t2S∂t1w1 + λw1 + f2w1 = 0.
and λ is a function which depends on slow and very slowvariables:
λ(x1, t1, x2, t2) = ε−1(−
(∂t2φ±
)2+
(∂x2φ±
)2+ 1
)Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Scattering problem
Our goal is to solve a scattering problem for the local parametricresonance equation. This problem is solved by four steps.
Obtain an asymptotic reduction to
the ordinary primary parametric resonance equation
i dWdσ + σW + FW = 0
Solve this equation using the parabolic cylinder functions.
Use formula for the solution to solve a scattering problem.
Estimate a domain of validity for the internal asymptoticsolution.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Scattering problem
Our goal is to solve a scattering problem for the local parametricresonance equation. This problem is solved by four steps.
Obtain an asymptotic reduction to
the ordinary primary parametric resonance equation
i dWdσ + σW + FW = 0
Solve this equation using the parabolic cylinder functions.
Use formula for the solution to solve a scattering problem.
Estimate a domain of validity for the internal asymptoticsolution.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Scattering problem
Our goal is to solve a scattering problem for the local parametricresonance equation. This problem is solved by four steps.
Obtain an asymptotic reduction to
the ordinary primary parametric resonance equation
i dWdσ + σW + FW = 0
Solve this equation using the parabolic cylinder functions.
Use formula for the solution to solve a scattering problem.
Estimate a domain of validity for the internal asymptoticsolution.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Scattering problem
Our goal is to solve a scattering problem for the local parametricresonance equation. This problem is solved by four steps.
Obtain an asymptotic reduction to
the ordinary primary parametric resonance equation
i dWdσ + σW + FW = 0
Solve this equation using the parabolic cylinder functions.
Use formula for the solution to solve a scattering problem.
Estimate a domain of validity for the internal asymptoticsolution.
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Matching asymptotic expansions and connection formula
In the domain l > 0 the formal asymptotic solution has the sameform
U(x , t, ε) ∼ εv1(x1, t1, t2) exp{i(kx + ωt)}+ c .c ..
The amplitude v1 = Ψ+ exp
{if 2
4ωG (x2, t2)
}and Ψ is determined
by the nonlinear Schrodinger equation also and initial datum onthe curve l = 0
Ψ+(t2, ζ)|l=0 = ef 2π8 Ψ− +
(1 + i)ef 2π16 e i f 2
16ln(2)f
√π
2Γ(1− i f 2
8 )Ψ−,
where ψ = Ψ(t2, ζ)|l=−0Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Conclutions
We construct the small asymptotic solution for the parametricperturbed Klein-Gordon equation.
The shape of this solution defines by NSE.
This approximation is valid before and after the parametricresonant curve.
On this curve the solution has a jump. The solution of NSEbefore the line and after the line are connected by:
Ψ+(t2, ζ)|l=0 =
ef 2π8 Ψ−(t2, ζ)|l=0 + (1+i)e
f 2π16 e i f 2
16 ln(2)f√
π
2Γ(1−i f 2
8)
Ψ−(t2, ζ)|l=0,
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Conclutions
We construct the small asymptotic solution for the parametricperturbed Klein-Gordon equation.
The shape of this solution defines by NSE.
This approximation is valid before and after the parametricresonant curve.
On this curve the solution has a jump. The solution of NSEbefore the line and after the line are connected by:
Ψ+(t2, ζ)|l=0 =
ef 2π8 Ψ−(t2, ζ)|l=0 + (1+i)e
f 2π16 e i f 2
16 ln(2)f√
π
2Γ(1−i f 2
8)
Ψ−(t2, ζ)|l=0,
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Conclutions
We construct the small asymptotic solution for the parametricperturbed Klein-Gordon equation.
The shape of this solution defines by NSE.
This approximation is valid before and after the parametricresonant curve.
On this curve the solution has a jump. The solution of NSEbefore the line and after the line are connected by:
Ψ+(t2, ζ)|l=0 =
ef 2π8 Ψ−(t2, ζ)|l=0 + (1+i)e
f 2π16 e i f 2
16 ln(2)f√
π
2Γ(1−i f 2
8)
Ψ−(t2, ζ)|l=0,
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Conclutions
We construct the small asymptotic solution for the parametricperturbed Klein-Gordon equation.
The shape of this solution defines by NSE.
This approximation is valid before and after the parametricresonant curve.
On this curve the solution has a jump. The solution of NSEbefore the line and after the line are connected by:
Ψ+(t2, ζ)|l=0 =
ef 2π8 Ψ−(t2, ζ)|l=0 + (1+i)e
f 2π16 e i f 2
16 ln(2)f√
π
2Γ(1−i f 2
8)
Ψ−(t2, ζ)|l=0,
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
New results
Primary parametric resonance partial differential equation
i∂x2S∂x1w1 − i∂t2S∂t1w1 + λw1 +f
2w1 = 0.
Connection formula:
Ψ+(t2, ζ)|l=0 = ef 2π8 Ψ−(t2, ζ)|l=0 +
(1 + i)ef 2π16 e i f 2
16ln(2)f
√π
2Γ(1− i f 2
8 )Ψ−(t2, ζ)|l=0,
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
New results
Primary parametric resonance partial differential equation
i∂x2S∂x1w1 − i∂t2S∂t1w1 + λw1 +f
2w1 = 0.
Connection formula:
Ψ+(t2, ζ)|l=0 = ef 2π8 Ψ−(t2, ζ)|l=0 +
(1 + i)ef 2π16 e i f 2
16ln(2)f
√π
2Γ(1− i f 2
8 )Ψ−(t2, ζ)|l=0,
Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance
Bibliography
Preprint: arXiv:0806.3338
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Oleg Kiselev, Institute of Mathematics, Ufa, Russia Scattering on a local parametric resonance