卡馬薩-霍爾姆方程 (Camassa Holm equation)是流體力學中的一個非線性偏微分方程
u
t
+
2
κ
u
x
−
u
x
x
t
+
3
u
u
x
=
2
u
x
u
x
x
+
u
u
x
x
x
.
{\displaystyle u_{t}+2\kappa u_{x}-u_{xxt}+3uu_{x}=2u_{x}u_{xx}+uu_{xxx}.\,}
1993年卡馬薩和霍爾姆以此偏微分方程模擬淺水波[ 1] ,
其中κ是大於0的參數。
卡馬薩-霍爾姆方程3D動畫
卡馬薩-霍爾姆方程有行波解[ 2] :
u
2
:=
(
3
/
2
)
∗
c
∗
(
c
−
2
∗
κ
)
(
c
o
s
h
(
(
1
/
2
)
∗
(
(
c
−
2
∗
κ
)
/
c
)
∗
(
−
x
−
x
0
+
c
∗
t
)
)
2
∗
(
κ
+
c
)
)
{\displaystyle u2:=(3/2)*{\frac {c*(c-2*\kappa )}{(cosh((1/2)*{\sqrt {((c-2*\kappa )/c)}}*(-x-x0+c*t))^{2}*(\kappa +c))}}}
參數:c = 1, x0 = 1, kappa = .3 代人得:
u
(
x
,
t
)
=
.463
c
o
s
h
(
−
.316
∗
x
−
.316
+
.316
∗
t
)
2
{\displaystyle u(x,t)={\frac {.463}{cosh(-.316*x-.316+.316*t)^{2}}}}
Maple 軟體包TWSolution可提供多種行波解[ 3] 。
sech 展開
g
[
2
]
:=
u
(
x
,
t
)
=
−
(
1
/
2
)
∗
k
a
p
p
a
+
C
5
∗
s
e
c
h
(
C
1
+
(
1
/
2
)
∗
s
q
r
t
(
3
)
∗
x
−
(
1
/
4
)
∗
k
a
p
p
a
∗
s
q
r
t
(
3
)
∗
t
)
2
{\displaystyle g[2]:={u(x,t)=-(1/2)*kappa+_{C}5*sech(_{C}1+(1/2)*sqrt(3)*x-(1/4)*kappa*sqrt(3)*t)^{2}}}
g
[
3
]
:=
u
(
x
,
t
)
=
−
(
1
/
2
)
∗
k
a
p
p
a
+
C
5
∗
s
e
c
h
(
C
1
−
(
1
/
2
)
∗
s
q
r
t
(
3
)
∗
x
+
(
1
/
4
)
∗
k
a
p
p
a
∗
s
q
r
t
(
3
)
∗
t
)
2
{\displaystyle g[3]:={u(x,t)=-(1/2)*kappa+_{C}5*sech(_{C}1-(1/2)*sqrt(3)*x+(1/4)*kappa*sqrt(3)*t)^{2}}}
g
[
4
]
:=
u
(
x
,
t
)
=
C
4
+
(
−
(
3
/
2
)
∗
C
4
−
(
3
/
4
)
∗
k
a
p
p
a
)
∗
s
e
c
h
(
C
1
+
(
1
/
2
∗
I
)
∗
s
q
r
t
(
3
)
∗
x
−
(
1
/
4
∗
I
)
∗
k
a
p
p
a
∗
s
q
r
t
(
3
)
∗
t
)
2
{\displaystyle g[4]:={u(x,t)=_{C}4+(-(3/2)*_{C}4-(3/4)*kappa)*sech(_{C}1+(1/2*I)*sqrt(3)*x-(1/4*I)*kappa*sqrt(3)*t)^{2}}}
g
[
5
]
:=
u
(
x
,
t
)
=
C
4
+
(
−
(
3
/
2
)
∗
C
4
−
(
3
/
4
)
∗
k
a
p
p
a
)
∗
s
e
c
h
(
C
1
−
(
1
/
2
∗
I
)
∗
s
q
r
t
(
3
)
∗
x
+
(
1
/
4
∗
I
)
∗
k
a
p
p
a
∗
s
q
r
t
(
3
)
∗
t
)
2
{\displaystyle g[5]:={u(x,t)=_{C}4+(-(3/2)*_{C}4-(3/4)*kappa)*sech(_{C}1-(1/2*I)*sqrt(3)*x+(1/4*I)*kappa*sqrt(3)*t)^{2}}}
g
[
6
]
:=
u
(
x
,
t
)
=
−
(
C
3
−
4
∗
C
3
∗
C
2
2
+
2
∗
k
a
p
p
a
∗
C
2
)
/
(
C
2
∗
(
3
+
4
∗
C
2
2
)
)
+
24
∗
C
2
∗
(
2
∗
C
3
+
k
a
p
p
a
∗
C
2
)
∗
s
e
c
h
(
C
1
+
C
2
∗
x
+
C
3
∗
t
)
2
/
(
16
∗
C
2
4
−
9
)
{\displaystyle g[6]:={u(x,t)=-(_{C}3-4*_{C}3*_{C}2^{2}+2*kappa*_{C}2)/(_{C}2*(3+4*_{C}2^{2}))+24*_{C}2*(2*_{C}3+kappa*_{C}2)*sech(_{C}1+_{C}2*x+_{C}3*t)^{2}/(16*_{C}2^{4}-9)}}
Camassa Holm equation traveling wave sech plot5
Camassa Holm equation traveling wave sech plot4
Camassa Holm equation traveling wave sech plot6
exp 展開
g
[
2
]
:=
u
(
x
,
t
)
=
−
(
1
/
9
)
∗
s
q
r
t
(
3
)
∗
C
3
−
(
1
/
3
)
∗
k
a
p
p
a
+
C
5
∗
e
x
p
(
C
1
−
s
q
r
t
(
3
)
∗
x
+
C
3
∗
t
)
{\displaystyle g[2]:={u(x,t)=-(1/9)*sqrt(3)*_{C}3-(1/3)*kappa+_{C}5*exp(_{C}1-sqrt(3)*x+_{C}3*t)}}
g
[
3
]
:=
u
(
x
,
t
)
=
(
1
/
9
)
∗
s
q
r
t
(
3
)
∗
C
3
−
(
1
/
3
)
∗
k
a
p
p
a
+
C
5
∗
e
x
p
(
C
1
+
s
q
r
t
(
3
)
∗
x
+
C
3
∗
t
)
{\displaystyle g[3]:={u(x,t)=(1/9)*sqrt(3)*_{C}3-(1/3)*kappa+_{C}5*exp(_{C}1+sqrt(3)*x+_{C}3*t)}}
g
[
5
]
:=
u
(
x
,
t
)
=
−
(
1
/
3
)
∗
s
q
r
t
(
3
)
∗
C
3
−
(
1
/
3
)
∗
k
a
p
p
a
+
C
7
∗
(
e
x
p
(
C
1
−
(
1
/
3
)
∗
s
q
r
t
(
3
)
∗
x
+
C
3
∗
t
)
)
3
{\displaystyle g[5]:={u(x,t)=-(1/3)*sqrt(3)*_{C}3-(1/3)*kappa+_{C}7*(exp(_{C}1-(1/3)*sqrt(3)*x+_{C}3*t))^{3}}}
Camassa Holm equation traveling wave exp plot2
Camassa Holm equation traveling wave exp plot3
Camassa Holm equation traveling wave exp plot5
csch 展開
g
[
2
]
:=
u
(
x
,
t
)
=
−
(
1
/
2
)
∗
k
a
p
p
a
+
C
5
∗
c
s
c
h
(
C
1
+
(
1
/
2
)
∗
s
q
r
t
(
3
)
∗
x
−
(
1
/
4
)
∗
k
a
p
p
a
∗
s
q
r
t
(
3
)
∗
t
)
2
{\displaystyle g[2]:={u(x,t)=-(1/2)*kappa+_{C}5*csch(_{C}1+(1/2)*sqrt(3)*x-(1/4)*kappa*sqrt(3)*t)^{2}}}
g
[
4
]
:=
u
(
x
,
t
)
=
C
4
+
(
(
3
/
2
)
∗
C
4
+
(
3
/
4
)
∗
k
a
p
p
a
)
∗
c
s
c
h
(
C
1
+
(
1
/
2
∗
I
)
∗
s
q
r
t
(
3
)
∗
x
−
(
1
/
4
∗
I
)
∗
k
a
p
p
a
∗
s
q
r
t
(
3
)
∗
t
)
2
{\displaystyle g[4]:={u(x,t)=_{C}4+((3/2)*_{C}4+(3/4)*kappa)*csch(_{C}1+(1/2*I)*sqrt(3)*x-(1/4*I)*kappa*sqrt(3)*t)^{2}}}
g
[
6
]
:=
u
(
x
,
t
)
=
−
(
C
3
−
4
∗
C
3
∗
C
2
2
+
2
∗
k
a
p
p
a
∗
C
2
)
/
(
C
2
∗
(
4
∗
C
2
2
+
3
)
)
−
24
∗
C
2
∗
(
2
∗
C
3
+
k
a
p
p
a
∗
C
2
)
∗
c
s
c
h
(
C
1
+
C
2
∗
x
+
C
3
∗
t
)
2
/
(
16
∗
C
2
4
−
9
)
{\displaystyle g[6]:={u(x,t)=-(_{C}3-4*_{C}3*_{C}2^{2}+2*kappa*_{C}2)/(_{C}2*(4*_{C}2^{2}+3))-24*_{C}2*(2*_{C}3+kappa*_{C}2)*csch(_{C}1+_{C}2*x+_{C}3*t)^{2}/(16*_{C}2^{4}-9)}}
Camassa Holm equation traveling wave csch plot2
Camassa Holm equation traveling wave csch plot4
Camassa Holm equation traveling wave csch plot6
sec 展開
g
[
3
]
:=
u
(
x
,
t
)
=
−
(
1
/
2
)
∗
k
a
p
p
a
+
C
5
∗
s
e
c
(
C
1
−
(
1
/
2
∗
I
)
∗
s
q
r
t
(
3
)
∗
x
+
(
1
/
4
∗
I
)
∗
k
a
p
p
a
∗
s
q
r
t
(
3
)
∗
t
)
2
{\displaystyle g[3]:={u(x,t)=-(1/2)*kappa+_{C}5*sec(_{C}1-(1/2*I)*sqrt(3)*x+(1/4*I)*kappa*sqrt(3)*t)^{2}}}
g
[
5
]
:=
u
(
x
,
t
)
=
C
4
+
(
−
(
3
/
2
)
∗
C
4
−
(
3
/
4
)
∗
k
a
p
p
a
)
∗
s
e
c
(
C
1
−
(
1
/
2
)
∗
s
q
r
t
(
3
)
∗
x
+
(
1
/
4
)
∗
k
a
p
p
a
∗
s
q
r
t
(
3
)
∗
t
)
2
{\displaystyle g[5]:={u(x,t)=_{C}4+(-(3/2)*_{C}4-(3/4)*kappa)*sec(_{C}1-(1/2)*sqrt(3)*x+(1/4)*kappa*sqrt(3)*t)^{2}}}
g
[
6
]
:=
u
(
x
,
t
)
=
(
C
3
+
4
∗
C
3
∗
C
2
2
+
2
∗
k
a
p
p
a
∗
C
2
)
/
(
C
2
∗
(
4
∗
C
2
2
−
3
)
)
−
24
∗
C
2
∗
(
2
∗
C
3
+
k
a
p
p
a
∗
C
2
)
∗
s
e
c
(
C
1
+
C
2
∗
x
+
C
3
∗
t
)
2
/
(
16
∗
C
2
4
−
9
)
{\displaystyle g[6]:={u(x,t)=(_{C}3+4*_{C}3*_{C}2^{2}+2*kappa*_{C}2)/(_{C}2*(4*_{C}2^{2}-3))-24*_{C}2*(2*_{C}3+kappa*_{C}2)*sec(_{C}1+_{C}2*x+_{C}3*t)^{2}/(16*_{C}2^{4}-9)}}
JacobiSN 展開
g
[
3
]
:=
u
(
x
,
t
)
=
(
1
/
9
∗
I
)
∗
s
q
r
t
(
3
)
∗
C
4
−
(
1
/
3
)
∗
k
a
p
p
a
+
C
6
∗
s
i
n
(
C
2
−
I
∗
s
q
r
t
(
3
)
∗
x
+
C
4
∗
t
)
{\displaystyle g[3]:={u(x,t)=(1/9*I)*sqrt(3)*_{C}4-(1/3)*kappa+_{C}6*sin(_{C}2-I*sqrt(3)*x+_{C}4*t)}}
g
[
4
]
:=
u
(
x
,
t
)
=
−
(
2
/
9
∗
I
)
∗
s
q
r
t
(
3
)
∗
C
4
−
(
1
/
2
)
∗
C
7
−
(
1
/
3
)
∗
k
a
p
p
a
+
C
7
∗
s
i
n
(
C
2
+
(
1
/
2
∗
I
)
∗
s
q
r
t
(
3
)
∗
x
+
C
4
∗
t
)
2
{\displaystyle g[4]:={u(x,t)=-(2/9*I)*sqrt(3)*_{C}4-(1/2)*_{C}7-(1/3)*kappa+_{C}7*sin(_{C}2+(1/2*I)*sqrt(3)*x+_{C}4*t)^{2}}}
Camassa Holm equation traveling wave Jacobish plot4
{\displaystyle }
{\displaystyle }
{\displaystyle }
{\displaystyle }
{\displaystyle }
^ Camassa & Holm 1993
^ Beals, Sattinger & Szmigielski 1999
^ Inna Shingareva, Carlos Lizárraga-Celaya,Solving Nonlinear Partial Differential Equations with Maple Page 27-35
Beals, Richard; Sattinger, David H.; Szmigielski, Jacek, Multi-peakons and a theorem of Stieltjes, Inverse Problems 15 (1), 1999, 15 (1): L1–L4, Bibcode:1999InvPr..15L...1B , arXiv:solv-int/9903011 , doi:10.1088/0266-5611/15/1/001
Boldea, Costin-Radu, A generalization for peakon's solitary wave and Camassa–Holm equation , General Mathematics 5 (1–4), 1995, 5 (1–4): 33–42 [2013-12-30 ] , (原始內容存檔 於2020-07-06)
Boutet de Monvel, Anne; Kostenko, Aleksey; Shepelsky, Dmitry; Teschl, Gerald , Long-Time Asymptotics for the Camassa–Holm Equation, SIAM J. Math. Anal. 41 (4), 2009, 41 (4): 1559–1588, arXiv:0902.0391 , doi:10.1137/090748500
Bressan, Alberto; Constantin, Adrian, Global conservative solutions of the Camassa–Holm equation , Arch. Ration. Mech. Anal. 183 (2), 2007a, 183 (2): 215–239 [2013-12-30 ] , Bibcode:2007ArRMA.183..215B , doi:10.1007/s00205-006-0010-z , (原始內容存檔 於2020-08-04)
Bressan, Alberto; Constantin, Adrian, Global dissipative solutions of the Camassa–Holm equation , Anal. Appl. 5 , 2007b, 5 : 1–27 [2013-12-30 ] , doi:10.1142/S0219530507000857 , (原始內容存檔 於2016-03-05)
Camassa, Roberto; Holm, Darryl D., An integrable shallow water equation with peaked solitons, Phys. Rev. Lett. 71 (11), 1993, 71 (11): 1661–1664, Bibcode:1993PhRvL..71.1661C , arXiv:patt-sol/9305002 , doi:10.1103/PhysRevLett.71.1661
Constantin, Adrian, Existence of permanent and breaking waves for a shallow water equation: a geometric approach , Annales de l'Institut Fourier 50 (2), 2000, 50 (2): 321–362 [2013-12-30 ] , (原始內容存檔 於2016-03-03)
Constantin, Adrian, On the scattering problem for the Camassa–Holm equation, R. Soc. Lond. Proc. Ser. A Math. Phys. Eng. Sci. 457 (2008), 2001, 457 (2008): 953–970, Bibcode:2001RSPSA.457..953C , doi:10.1098/rspa.2000.0701
Constantin, Adrian; Escher, Joachim, Wave breaking for nonlinear nonlocal shallow water equations, Acta Math. 181 (2), 1998b, 181 (2): 229–243, doi:10.1007/BF02392586
Constantin, Adrian; Escher, Joachim, On the blow-up rate and the blow-up set of breaking waves for a shallow water equation, Math. Z. 233 (1), 2000, 233 (1): 75–91, doi:10.1007/PL00004793
Constantin, Adrian; McKean, Henry P., A shallow water equation on the circle, Commun. Pure Appl. Math. 52 (8), 1999, 52 (8): 949–982, doi:10.1002/(SICI)1097-0312(199908)52:8<949::AID-CPA3>3.0.CO;2-D
Constantin, Adrian; Strauss, Walter A., Stability of peakons, Comm. Pure Appl. Math., 2000, 53 (5): 603–610, doi:10.1002/(SICI)1097-0312(200005)53:5<603::AID-CPA3>3.0.CO;2-L
Constantin, Adrian; Strauss, Walter A., Stability of the Camassa–Holm solitons, J. Nonlinear Sci., 2002, 12 (4): 415–422, Bibcode:2002JNS....12..415C , doi:10.1007/s00332-002-0517-x
Constantin, Adrian; Gerdjikov, Vladimir S.; Ivanov, Rossen I., Inverse scattering transform for the Camassa–Holm equation, Inverse Problems 22 (6), 2006, 22 (6): 2197–2207, Bibcode:2006InvPr..22.2197C , arXiv:nlin/0603019 , doi:10.1088/0266-5611/22/6/017
Eckhardt, Jonathan; Teschl, Gerald , On the isospectral problem of the dispersionless Camassa-Holm equation, Adv. Math. 235 (1), 2013, 235 (1): 469–495, arXiv:1205.5831 , doi:10.1016/j.aim.2012.12.006
Loubet, Enrique, About the explicit characterization of Hamiltonians of the Camassa–Holm hierarchy, J. Nonlinear Math. Phys. 12 (1), 2005, 12 (1): 135–143, Bibcode:2005JNMP...12..135L , doi:10.2991/jnmp.2005.12.1.11
McKean, Henry P., Fredholm determinants and the Camassa–Holm hierarchy, Comm. Pure Appl. Math. 56 (5), 2003a, 56 (5): 638–680, doi:10.1002/cpa.10069
McKean, Henry P., Breakdown of the Camassa–Holm equation, Comm. Pure Appl. Math. 57 (3), 2004, 57 (3): 416–418, doi:10.1002/cpa.20003
Parker, Allen, On the Camassa–Holm equation and a direct method of solution. III. N -soliton solutions, Proc. R. Soc. Lond. Ser. A Math. Phys. Eng. Sci. 461 (2064), 2005b, 461 (2064): 3893–3911, Bibcode:2005RSPSA.461.3893P , doi:10.1098/rspa.2005.1537
Liao, S.J. , Do peaked solitary water waves indeed exist?, Communications in Nonlinear Science and Numerical Simulation, 2013, doi:10.1016/j.cnsns.2013.09.042
*谷超豪 《孤立子 理論中的達布變換 及其幾何應用》 上海科學技術出版社
*閻振亞著 《複雜非線性波的構造性理論及其應用》 科學出版社 2007年
李志斌編著 《非線性數學物理方程的行波解》 科學出版社
王東明著 《消去法及其應用》 科學出版社 2002
*何青 王麗芬編著 《Maple 教程》 科學出版社 2010 ISBN 9787030177445
Graham W. Griffiths William E.Shiesser Traveling Wave Analysis of Partial Differential p135 Equations Academy Press
Richard H. Enns George C. McCGuire, Nonlinear Physics Birkhauser,1997
Inna Shingareva, Carlos Lizárraga-Celaya,Solving Nonlinear Partial Differential Equations with Maple Springer.
Eryk Infeld and George Rowlands,Nonlinear Waves,Solitons and Chaos,Cambridge 2000
Saber Elaydi,An Introduction to Difference Equationns, Springer 2000
Dongming Wang, Elimination Practice,Imperial College Press 2004
David Betounes, Partial Differential Equations for Computational Science: With Maple and Vector Analysis Springer, 1998 ISBN 9780387983004
George Articolo Partial Differential Equations & Boundary Value Problems with Maple V Academic Press 1998 ISBN 9780120644759