The coupling integrable couplings of the generalized coupled Burgers equation hierarchy and its Hamiltonian structure

Wei, Yuan; Yin, Li; Long, Xin

doi:10.1186/s13662-019-2004-9

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Open access
Published: 12 February 2019

The coupling integrable couplings of the generalized coupled Burgers equation hierarchy and its Hamiltonian structure

Yuan Wei¹,
Li Yin¹ &
Xin Long^2,3

Advances in Difference Equations volume 2019, Article number: 58 (2019) Cite this article

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Abstract

In this paper, we mainly give the Lie algebras E, F and H of three kinds and their commutator, respectively. Next, we establish three isospectral problems with the help of their corresponding loop algebras Ẽ, F̃, and H̃. Based on on the Tu scheme, coupling integrable couplings of three kinds for the generalized coupled Burgers equation hierarchy are obtained. Finally, we obtain the Hamiltonian structure of one of the coupling integrable couplings of the generalized coupled Burgers equation hierarchy by using the quadratic-form identity.

1 Introduction

The development of soliton theory has undergone a rapid development in the 1960s. Integrable couplings are a new important and interesting topic in the field of soliton theory [1,2,3]. A lot of integrable nonlinear evolution equations, such as the Schroedinger equation and the KdV equation, were discussed. The notion of integrable couplings was first introduced by Virasoro [4, 5]. Integrable couplings are coupled systems of integrable equations which contain given integrable equations as their sub-systems [6]. Integrable couplings have much richer mathematical structures than scalar integrable equations [7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31]. Recently, Inc, Yusuf, Aliyu and Baleanu discussed a Lie symmetry analysis and conservation laws for the time fractional simplified modified Kawahara equation, the generalized shallow water wave equation, the time fractional dispersive long-wave equation and the time fractional generalized Burgers–Huxley equation. They also studied a time fractional third-order variant Boussinesq system and gave a symmetry analysis, explicit solutions, conservation laws and numerical approximations [32,33,34,35,36,37]. So it is important to study integrable couplings in soliton theory. Zhang even proposed an efficient method for constructing nonlinear evolution equations and their resulting Hamiltonian structure. Ma called it the Tu scheme. Hence, Hu developed the trace identity, and got an efficient method to work out the soliton equations and the Hamiltonian structure. In [38] Zhang gave three kinds of coupling integrable couplings of the KdV hierarchy of evolution equations. The three Lie algebras E, F and H in [38] can be used to obtain the other coupling integrable couplings of the soliton equations. In this paper, we introduce three higher-dimensional Lie algebras and their corresponding loop algebras Ẽ, F̃, and H̃, and consider three Lax pairs for the zero curvature equation

$$ V_{x}=[U,V]. $$

(1.1)

With the help of the loop algebras, we obtain three kinds of coupling integrable couplings of the generalized coupled Burgers equation hierarchy. And the one coupling integrable coupling of the generalized coupled Burgers equation hierarchy has a Hamiltonian structure obtained by employing the quadratic-form identity [39].

2 Three higher-dimensional Lie algebras

Let

$$E=\operatorname{span}\{e_{1},e_{2},e_{3},e_{4},e_{5},e_{6},e_{7} \}. $$

For $\forall a=\sum^{7}_{i=1}a_{i}e_{i}$, $b=\sum^{7}_{i=1}b_{i}e_{i} \in E$, we have

[a, b] = (\begin{array}{c} 2 a_{3} b_{2} - 2 a_{2} b_{3} \\ 2 a_{1} b_{3} - 2 a_{3} b_{1} \\ 2 a_{1} b_{2} - 2 a_{2} b_{1} \\ a_{1} b_{4} - a_{4} b_{1} + a_{2} b_{5} - a_{5} b_{2} + a_{3} b_{5} - a_{5} b_{3} \\ a_{5} b_{1} - a_{1} b_{5} + a_{2} b_{4} - a_{4} b_{2} + a_{4} b_{3} - a_{3} b_{4} \\ a_{1} b_{6} - a_{6} b_{1} + a_{2} b_{7} - a_{7} b_{2} + a_{3} b_{7} - a_{7} b_{3} \\ a_{7} b_{1} - a_{7} b_{1} + a_{2} b_{6} - a_{6} b_{2} + a_{6} b_{3} - a_{3} b_{6} \end{array}) .

(2.1)

It is easy to see that E is a Lie algebra equipped with the commutator (2.1).

Denote

$$F=\operatorname{span}\{f_{1},f_{2},f_{3},f_{4},f_{5},f_{6},f_{7},f_{8},f_{9} \}. $$

For $\forall a=\sum^{7}_{i=1}a_{i}f_{i}$, $b=\sum^{7}_{i=1}b_{i}f_{i} \in L_{2}$, we easily obtain

[a, b] = (\begin{array}{c} 2 a_{3} b_{2} - 2 a_{2} b_{3} \\ 2 a_{1} b_{3} - 2 a_{3} b_{1} \\ 2 a_{1} b_{2} - 2 a_{2} b_{1} \\ 2 a_{7} b_{2} - 2 a_{2} b_{7} + 2 a_{3} b_{6} - 2 a_{6} b_{3} \\ 2 a_{3} b_{8} - 2 a_{8} b_{3} + 2 a_{9} b_{2} - 2 a_{2} b_{9} \\ 2 a_{1} b_{7} - 2 a_{7} b_{1} + 2 a_{4} b_{3} - 2 a_{3} b_{4} \\ 2 a_{1} b_{6} - 2 a_{6} b_{1} + 2 a_{4} b_{2} - 2 a_{2} b_{4} \\ 2 a_{1} b_{9} - 2 a_{9} b_{1} + 2 a_{5} b_{3} - 2 a_{3} b_{5} \\ 2 a_{1} b_{8} - 2 a_{8} b_{1} + 2 a_{5} b_{2} - 2 a_{2} b_{5} \end{array})

(2.2)

and F is a Lie algebra equipped with the commutator (2.2).

The Lie algebras E and F are all expanding Lie algebra of the well-known Lie algebra

$$R^{3}=\bigl\{ r=(r_{1},r_{2},r_{3})^{T},r_{i} \in R\bigr\} , $$

which along with the commutator leads to

[a, b] = (\begin{array}{c} 2 a_{3} b_{2} - 2 a_{2} b_{3} \\ 2 a_{1} b_{3} - 2 a_{3} b_{1} \\ 2 a_{1} b_{2} - 2 a_{2} b_{1} \end{array}) \forall a = {(a_{1}, a_{2}, a_{3})}^{T}, b = {(b_{1}, b_{2}, b_{3})}^{T} \in R^{3} .

(2.3)

Assume that $L_{s}$ is a s-dim Lie algebra,

K (L_{s}) = {A = (\begin{array}{c} A_{1} \\ A_{2} \\ A_{3} \end{array}), A_{i} \in L_{s}, i = 1, 2, 3} .

For

B = (\begin{array}{c} B_{1} \\ B_{2} \\ B_{3} \end{array}) \in K (L_{s})

and

$$[A,B]=\bigl([A_{1},B_{1}],[A_{1},B_{2}]+ [A_{2},B_{1}],[A_{1},B_{3}]+ [A_{3},B_{1}]+[A_{3}+B_{3}] \bigr)^{T} \in K(L_{s}), $$

$K(L_{s})$ is a Lie algebra. By taking $s=3$ and $[A_{1},B_{1}]$ is the same as (2.3), then we can get another Lie algebra $K(L_{s})$, which can be denoted H. The Lie algebra H is isomorphic to the Lie algebra F,

$$H=\operatorname{span}\{f_{1},f_{2},f_{3},f_{4},f_{5},f_{6},f_{7},f_{8},f_{9} \}, $$

along with the commutator

[a, b] = (\begin{array}{c} 2 a_{3} b_{2} - 2 a_{2} b_{3} \\ 2 a_{1} b_{3} - 2 a_{3} b_{1} \\ 2 a_{1} b_{2} - 2 a_{2} b_{1} \\ 2 a_{3} b_{5} - 2 a_{5} b_{3} + 2 a_{6} b_{2} - 2 a_{2} b_{6} \\ 2 a_{1} b_{6} - 2 a_{6} b_{1} + 2 a_{4} b_{3} - 2 a_{3} b_{4} \\ 2 a_{1} b_{5} - 2 a_{5} b_{1} + 2 a_{4} b_{2} - 2 a_{2} b_{4} \\ 2 a_{3} b_{8} - 2 a_{8} b_{3} + 2 a_{9} b_{2} - 2 a_{2} b_{9} + 2 a_{9} b_{8} - 2 a_{8} b_{9} \\ 2 a_{1} b_{9} - 2 a_{9} b_{1} + 2 a_{7} b_{3} - 2 a_{3} b_{7} + 2 a_{7} b_{9} - 2 a_{9} b_{7} \\ 2 a_{1} b_{8} - 2 a_{8} b_{1} + 2 a_{7} b_{2} - 2 a_{2} b_{7} + 2 a_{7} b_{8} - 2 a_{8} b_{7} \end{array}),

(2.4)

where $a=\sum_{i=1}^{9}a_{i}e_{i}$, $b=\sum_{i=1}^{9}b_{i}e_{i}$.

By applying Lie algebra E, F and H, we can obtain three kinds of coupling integrable couplings of the generalized coupled Burgers equation hierarchy.

3 Three kinds of coupling integrable couplings of the generalized coupled Burgers equation hierarchy

In this section, we shall show how to get three kinds of coupling integrable couplings of the generalized coupled Burgers equation hierarchy by making use of the Lie algebra E, F and H.

(I) The first kind of coupling integrable couplings of the generalized coupled Burgers equation hierarchy.

The loop algebra of Lie algebra E is given by $\widetilde{E}=\operatorname{span}\{ e_{i}(n)=e_{i}\lambda^{n},i=1,2,3,4,5,6,7\}$, $[e_{i}(m),e_{j}(n)]=[e_{i},e_{j}]\lambda^{m+n}$, $m,n\in Z$, $i,j=1,2,3,4,5,6,7$, equipped with the commutator (2.1). Consider a Lax pair for zero curvature equation as follows:

$$ \textstyle\begin{cases} U=e_{1}(1)+qh_{2}(0)+h_{2}(1)+rh_{3}(0)+u_{1}h_{4}(0)+u_{2}h_{5}(0)+s_{1}h_{6}(0)+s_{2}h_{7}(0), \\ V=\sum_{m\geq 0}(V_{1m}h_{1}(-m)+V_{2m}h_{2}(-m)+V_{3m}h_{3}(-m)+V_{4m}h_{4}(-m) \\ \hphantom{V={}}{}+V_{5m}h_{5}(-m)+V_{6m}h_{6}(-m)+V_{7m}h_{7}(-m)). \end{cases} $$

(3.1)

The stationary zero equation

$$ V_{x}=[U,V] $$

(3.2)

changes into

$$ \textstyle\begin{cases} V_{1,mx}=-2V_{3,m+1}-2qV_{3m}+2rV_{2m}, \\ V_{2,mx}=2V_{3m}-2rV_{1m}, \\ V_{3,mx}=-2V_{1,m+1}-2qV_{1m}+2V_{2m}, \\ V_{4,mx}=V_{5,m+1}+qV_{5m}+V_{4m}-u_{1}V_{1m}-u_{2}V_{2m}+rV_{5m}-u_{2}V_{3m}, \\ V_{5,mx}=V_{4,m+1}+qV_{4m}+u_{2}V_{1m}-V_{5m}-u_{1}V_{2m}+u_{1}V_{3m}-rV_{4m}, \\ V_{6,mx}=V_{7,m+1}+qV_{7m}+V_{6m}-s_{1}V_{1m}-s_{2}V_{2m}+rV_{7m}-s_{2}V_{3m}, \\ V_{7,mx}=V_{6,m+1}+qV_{6m}+s_{2}V_{1m}-V_{7m}-s_{1}V_{2m}+s_{1}V_{3m}-rV_{6m}. \end{cases} $$

(3.3)

Denoting

$$\begin{aligned} V_{+}^{(n)} =&\sum_{m=0}^{n} \bigl(V_{1m}h_{1}(n-m)+V_{2m}h_{2}(n-m)+V_{3m}h_{3}(n-m)+V_{4m}h_{4}(n-m) \\ &{}+V_{5m}h_{5}(n-m)+V_{6m}h_{6}(n-m)+V_{7m}h_{7}(n-m) \bigr), \end{aligned}$$

the stationary zero curvature equation (3.2) can be decomposed into

$$-V_{+x}^{(n)}+\bigl[U,V_{+}^{(n)} \bigr]=V_{-x}^{(n)}-\bigl[U,V_{-}^{(n)} \bigr]. $$

Simple computation results in

$$\begin{aligned} -V_{+x}^{(n)}+\bigl[U,V_{+}^{(n)} \bigr] =&2V_{3,n+1}h_{1}(0)+2V_{1,n+1}h_{3}(0)-V_{5,n+1}h_{4}(0)-V_{4,n+1}h_{5}(0) \\ &{}-V_{7,n+1}h_{6}(0)-V_{6,n+1}h_{7}(0). \end{aligned}$$

Taking $V^{(n)}=V_{+}^{(n)}-\frac{1}{r}V_{3,n+1}h_{2}(0)$, we have

$$\begin{aligned} -V_{x}^{(n)}+\bigl[U,V^{(n)}\bigr] =&\biggl( \frac{1}{r}V_{3,n+1}\biggr)_{x}h_{2}(0)- \frac {1}{r}V_{2,n+1x}h_{3}(0) \\ &{}+\biggl(-V_{5,n+1}+ \frac{u_{2}}{r}V_{3,n+1}\biggr)h_{4}(0) \\ &{}+ \biggl(-V_{4,n+1}+\frac{u_{1}}{r}V_{3,n+1}\biggr)h_{5}(0)+\biggl(-V_{7,n+1}+\frac {s_{2}}{r}V_{3,n+1} \biggr)h_{6}(0) \\ &{}+\biggl(-V_{6,n+1}+\frac {s_{1}}{r}V_{3,n+1} \biggr)h_{7}(0). \end{aligned}$$

Hence the zero curvature equation

$$ U_{t}-V_{x}^{(n)}+ \bigl[U,V^{(n)}\bigr]=0 $$

(3.4)

gives rise to the Lax integrable hierarchy

u_{t} = {(\begin{array}{c} q \\ r \\ u_{1} \\ u_{2} \\ s_{1} \\ s_{2} \end{array})}_{t} = (\begin{array}{c} - \partial (\frac{1}{r} V_{3, n + 1}) \\ \frac{1}{r} \partial (V_{2, n + 1}) \\ V_{5, n + 1} - \frac{u_{2}}{r} V_{3, n + 1} \\ V_{4, n + 1} - \frac{u_{1}}{r} V_{3, n + 1} \\ V_{7, n + 1} - \frac{s_{2}}{r} V_{3, n + 1} \\ V_{6, n + 1} - \frac{s_{1}}{r} V_{3, n + 1} \end{array}) .

(3.5)

When we take $s_{1}=s_{2}=0$, (3.5) can be reduced to an integrable coupling of the generalized coupled Burgers equation hierarchy,

u_{t} = {(\begin{array}{c} q \\ r \\ u_{1} \\ u_{2} \end{array})}_{t} = (\begin{array}{c} - \partial (\frac{1}{r} V_{3, n + 1}) \\ \frac{1}{r} \partial (V_{2, n + 1}) \\ V_{5, n + 1} - \frac{u_{2}}{r} V_{3, n + 1} \\ V_{4, n + 1} - \frac{u_{1}}{r} V_{3, n + 1} \end{array}) .

(3.6)

And (3.4) can be reduced to another generalized coupled Burgers equation hierarchy by taking $u_{1}=u_{2}=0$,

u_{t} = {(\begin{array}{c} q \\ r \\ s_{1} \\ s_{2} \end{array})}_{t} = (\begin{array}{c} - \partial (\frac{1}{r} V_{3, n + 1}) \\ \frac{1}{r} \partial (V_{2, n + 1}) \\ V_{7, n + 1} - \frac{s_{2}}{r} V_{3, n + 1} \\ V_{6, n + 1} - \frac{s_{1}}{r} V_{3, n + 1} \end{array}) .

(3.7)

So we call (3.5) the first kind of coupling integrable couplings of the generalized coupled Burgers equation hierarchy.

When we set $V_{1,0}=0$, $V_{2,0}=\beta $, $V_{3,0}=V_{4,0}=V_{5,0}=V_{6,0}=V_{7,0}=0$, we can obtain $V_{1,1}=\beta$, $V_{2,1}=0$, $V_{3,1}=\beta r$, $V_{4,1}=\beta u_{1}$, $V_{5,1}=\beta u_{2} $, $V_{6,1}=\beta s_{1}$, $V_{7,1}=\beta s_{2} , \ldots $ .

Hence, when we take $n=2$ in Eq. (3.5), we obtain the first kind of the coupling integrable couplings of the generalized coupled Burgers equation, that is,

$$ \textstyle\begin{cases} q_{t}=-\beta(\frac{r_{xx}}{4r}+\frac{q_{x}}{r}+q^{2}+\frac {r^{2}}{2})_{x}, \\ r_{t}=\beta(\frac{r_{xx}}{2r}+\frac{q_{x}}{r}-q_{x}r-2qr_{x}), \\ u_{1t}=\beta u_{2xx}-2\beta u_{1x}q-\beta u_{1}q_{x}-\beta u_{2x}-\frac {\beta}{2}u_{1}r_{x}-\beta u_{1x}r-\beta\frac{u_{2}r_{xx}}{4r}-\beta \frac{u_{2}q_{x}}{2r}, \\ u_{2t}=\beta u_{1xx}-2\beta u_{2x}q-\beta u_{2}q_{x}+\beta u_{1x}+\frac {\beta}{2}u_{2}r_{x}+\beta u_{2x}r-\beta\frac{u_{1}r_{xx}}{4r}-\beta \frac{u_{1}q_{x}}{2r}, \\ s_{1t}=\beta s_{2xx}-2\beta s_{1x}q-\beta s_{1}q_{x}-\beta s_{2x}-\frac {\beta}{2}s_{1}r_{x}-\beta s_{1x}r-\beta\frac{s_{2}r_{xx}}{4r}-\beta \frac{s_{2}q_{x}}{2r}, \\ s_{2t}=\beta s_{1xx}-2\beta s_{2x}q-\beta s_{2}q_{x}+\beta s_{1x}+\frac {\beta}{2}s_{2}r_{x}+\beta s_{2x}r-\beta\frac{s_{1}r_{xx}}{4r}-\beta \frac{s_{1}q_{x}}{2r}. \end{cases} $$

(3.8)

When we take $u_{1}=u_{2}=s_{1}=s_{2}=0$, $\beta=-2$ in (3.9), we can get equations as follows:

$$ \textstyle\begin{cases} q_{t}=(\frac{r_{xx}}{2r}+\frac{q_{x}}{r}+2q^{2}+r^{2})_{x}, \\ r_{t}=-\frac{r_{xx}}{r} q_{xx}-\frac{2q_{x}}{r}+2q_{x}r+4qr_{x}. \end{cases} $$

(3.9)

And when we take $r=-1$ in (3.8), we can get the famous generalized Burgers equation

$$ q_{t}=4qq_{x}-q_{xx}. $$

(3.10)

(II) The second kind of coupling integrable couplings of the generalized coupled Burgers equation hierarchy.

We have the loop algebra of the Lie algebra F:

$$\begin{aligned}& \widetilde {F}=\operatorname{span}\bigl\{ f_{i}(n)=f_{i} \lambda^{n},i=1,2,3,4,5,6,7,8,9\bigr\} , \\& \bigl[f_{i}(m),f_{j}(n)\bigr]=[f_{i},f_{j}] \lambda^{m+n},\quad m,n\in Z,i,j=1,2,3,4,5,6,7,8,9, \end{aligned}$$

of which the resulting commutators are defined the same as (2.2).

By using the loop algebra F̃, we introduce an isospectral Lax pair for zero curvature equation as follows:

$$ \textstyle\begin{cases} U=f_{1}(0)+qf_{2}(0)+f_{2}(1)+rf_{3}(0)+u_{1}f_{4}(0)+u_{2}f_{5}(0)+s_{1}f_{7}(0)+s_{2}f_{9}(0), \\ V=\sum_{m\geq 0}(V_{1m}f_{1}(-m)+V_{2m}f_{2}(-m)+V_{3m}f_{3}(-m)+V_{4m}f_{4}(-m) \\ \hphantom{V={}}{}+V_{5m}f_{5}(-m)+V_{6m}f_{6}(-m)+V_{7m}f_{7}(-m)+V_{8m}f_{8}(-m)+V_{9m}f_{9}(-m)). \end{cases} $$

(3.11)

The stationary zero curvature

$$V_{x}=[U,V] $$

is presented by the recurrence relations as follows:

$$ \textstyle\begin{cases} V_{1,mx}=-2V_{3,m+1}-2qV_{3m}+2rV_{2m}, \\ V_{2,mx}=2V_{3m}-2rV_{1m}, \\ V_{3,mx}=-2V_{1,m+1}-2qV_{1m}+2V_{2m}, \\ V_{4,mx}=-2V_{7,m+1}-2qV_{7m}+2s_{1}V_{2m}+2rV_{6m}, \\ V_{5,mx}=-2V_{9,m+1}-2qV_{9m}+2s_{2}V_{2m}+2rV_{8m}, \\ V_{6,mx}=2V_{7m}-2s_{1}V_{1m}+2u_{1}V_{3m}-2rV_{4m}, \\ V_{7,mx}=-2V_{4,m+1}-2qV_{4m}++2u_{1}V_{2m}+2V_{6m}, \\ V_{8,mx}=2V_{9m}-2s_{2}V_{1m}+2u_{2}V_{3m}-2rV_{5m}, \\ V_{9,mx}=-2V_{5,m+1}-2qV_{5m}+2u_{2}V_{2m}+2V_{8m}. \end{cases} $$

(3.12)

Noting that

$$\begin{aligned} V_{+}^{(n)} =&\sum_{m=0}^{n} \bigl(V_{1m}f_{1}(n-m)+V_{2m}f_{2}(n-m)+V_{3m}f_{3}(n-m)+V_{4m}f_{4}(n-m) \\ &{}+V_{5m}f_{5}(n-m)+V_{6m}f_{6}(n-m)+V_{7m}f_{7}(n-m)+V_{8m}f_{8}(n-m)+V_{9m}f_{9}(n-m) \bigr), \end{aligned}$$

we obtain by a direct calculation

$$\begin{aligned} -V_{+x}^{(n)}+\bigl[U,V_{+}^{(n)} \bigr] =&2V_{3,n+1}f_{1}(0)+2V_{1,n+1}f_{3}(0)+2V_{7,n+1}f_{4}(0)+2V_{9,n+1}f_{5}(0) \\ &{}+2V_{4,n+1}f_{7}(0)+2V_{5,n+1}f_{9}(0). \end{aligned}$$

Taking $V^{(n)}=V_{+}^{(n)}-\frac{1}{r}V_{3,n+1}f_{2}(0)$, after a calculation, we get

$$\begin{aligned} -V_{x}^{(n)}+\bigl[U,V^{(n)}\bigr] =&\biggl( \frac{1}{r}V_{3,n+1}\biggr)_{x}f_{2}(0)- \frac {1}{r}V_{2,n+1x}f_{3}(0)+\biggl(2V_{7,n+1}- \frac {2s_{1}}{r}V_{3,n+1}\biggr)f_{4}(0) \\ &{}+\biggl(2V_{9,n+1}-\frac{2s_{2}}{r}V_{3,n+1} \biggr)f_{5}(0) +\biggl(2V_{4,n+1}-\frac{2u_{1}}{r}V_{3,n+1} \biggr)f_{7}(0) \\ &{}+\biggl(2V_{5,n+1}-\frac {2u_{2}}{r}V_{3,n+1} \biggr)f_{9}(0). \end{aligned}$$

The zero curvature equation

$$ U_{t}-V_{x}^{(n)}+ \bigl[U,V^{(n)}\bigr]=0 $$

(3.13)

admits

u_{t} = {(\begin{array}{c} q \\ r \\ u_{1} \\ u_{2} \\ s_{1} \\ s_{2} \end{array})}_{t} = (\begin{array}{c} - {(\frac{1}{r} V_{3, n + 1})}_{x} \\ \frac{1}{r} V_{2, n + 1 x} \\ - 2 V_{7, n + 1} + \frac{2 s_{1}}{r} V_{3, n + 1} \\ - 2 V_{9, n + 1} + \frac{2 s_{2}}{r} V_{3, n + 1} \\ - 2 V_{4, n + 1} + \frac{2 u_{1}}{r} V_{3, n + 1} \\ - 2 V_{5, n + 1} + \frac{2 u_{2}}{r} V_{3, n + 1} \end{array}),

(3.14)

which can be regarded as a composition of two integrable coupling of the generalized coupled Burgers equation hierarchy as follows:

u_{t} = {(\begin{array}{c} q \\ r \\ u_{1} \\ u_{2} \end{array})}_{t} = (\begin{array}{c} - {(\frac{1}{r} V_{3, n + 1})}_{x} \\ \frac{1}{r} V_{2, n + 1 x} \\ - 2 V_{7, n + 1} + \frac{2 s_{1}}{r} V_{3, n + 1} \\ - 2 V_{9, n + 1} + \frac{2 s_{2}}{r} V_{3, n + 1} \end{array}),

(3.15)

u_{t} = {(\begin{array}{c} q \\ r \\ s_{1} \\ s_{2} \end{array})}_{t} = (\begin{array}{c} - {(\frac{1}{r} V_{3, n + 1})}_{x} \\ \frac{1}{r} V_{2, n + 1 x} \\ - 2 V_{4, n + 1} + \frac{2 u_{1}}{r} V_{3, n + 1} \\ - 2 V_{5, n + 1} + \frac{2 u_{2}}{r} V_{3, n + 1} \end{array}) .

(3.16)

When we set $V_{1,0}=0$, $V_{2,0}=\beta $, $V_{3,0}=V_{4,0}=V_{5,0}=V_{6,0}=V_{7,0}=V_{8,0}=V_{9,0}=0$, we can obtain $V_{1,1}=\beta$, $V_{2,1}=0$, $V_{3,1}=\beta r$, $V_{4,1}=\beta u_{1}$, $V_{5,1}=\beta u_{2} $, $V_{6,1}=0$, $V_{7,1}=\beta s_{1}$, $V_{8,1}=0$, $V_{9,1}=\beta s_{2} , \ldots$ .

Hence, when we take $n=2$ in (3.14), we get the second kind of the coupling integrable couplings of the generalized coupled Burgers equation as follows:

$$ \textstyle\begin{cases} q_{t}=-\beta(\frac{r_{xx}}{4r}+\frac{q_{x}}{r}+q^{2}+\frac {r^{2}}{2})_{x}, \\ r_{t}=\beta(\frac{r_{xx}}{2r}+\frac{q_{x}}{r}-q_{x}r-2qr_{x}), \\ u_{1t}=-\frac{\beta}{2}s_{1xx}-2\beta u_{1x}q-\beta u_{1}q_{x}+2\beta u_{1}r-2\beta s_{1}r^{2}+\frac{\beta}{2} \frac{s_{1}r_{xx}}{r}+\beta \frac{s_{1}q_{x}}{r}, \\ u_{2t}=-\frac{\beta}{2}s_{2xx}-2\beta u_{2x}q-\beta u_{2}q_{x}+2\beta u_{2}r-2\beta s_{2}r^{2}+\frac{\beta}{2} \frac{s_{2}r_{xx}}{r}+\beta \frac{s_{2}q_{x}}{r}, \\ s_{1t}=-\frac{\beta}{2}u_{1xx}-2\beta s_{1x}q-\beta s_{1}q_{x}+2\beta u_{1}-2\beta s_{1}r+\frac{\beta}{2} \frac{u_{1}r_{xx}}{r}+\beta \frac {u_{1}q_{x}}{r}, \\ s_{2t}=-\frac{\beta}{2}u_{2xx}-2\beta s_{2x}q-\beta s_{2}q_{x}+2\beta u_{2}-2\beta s_{2}r+\frac{\beta}{2} \frac{u_{2}r_{xx}}{r}+\beta \frac {u_{2}q_{x}}{r}. \end{cases} $$

(3.17)

When take $u_{1}=u_{2}=s_{1}=s_{2}=0$, $r=-1$, $\beta=-2$ in (3.17), we can also get the same as (3.10).

(III) The third kind of coupling integrable couplings of the generalized coupled Burgers equation hierarchy.

By using the loop algebra of Lie algebra H as follows:

$$\widetilde{H}=\operatorname{span}\bigl\{ f_{i}(n)=f_{i} \lambda^{n},i=1,2,3,4,5,6,7,8,9\bigr\} , $$

along with the commutator

$$\bigl[f_{i}(m),f_{j}(n)\bigr]=[f_{i},f_{j}] \lambda^{m+n},\quad m,n\in Z,i,j=1,2,3,4,5,6,7,8,9, $$

we get the third type of coupling integrable couplings of the generalized coupled Burgers equation hierarchy.

A Lax pair for zero curvature equation is given as follows:

$$ \textstyle\begin{cases} U=f_{1}(0)+qf_{2}(0)+f_{2}(1)+rf_{3}(0)+u_{1}f_{4}(0)+u_{2}f_{6}(0)+s_{1}f_{7}(0)+s_{2}f_{9}(0), \\ V=\sum_{m\geq 0}(V_{1m}f_{1}(-m)+V_{2m}f_{2}(-m)+V_{3m}f_{3}(-m)+V_{4m}f_{4}(-m) \\ \hphantom{V={}}{}+V_{5m}f_{5}(-m)+V_{6m}f_{6}(-m)+V_{7m}f_{7}(-m)+V_{8m}f_{8}(-m)+V_{9m}f_{9}(-m)). \end{cases} $$

(3.18)

A solution to the stationary zero curvature equation

$$V_{x}=[U,V] $$

is presented now:

$$ \textstyle\begin{cases} V_{1,mx}=-2V_{3,m+1}-2qV_{3m}+2rV_{2m}, \\ V_{2,mx}=2V_{3m}-2rV_{1m}, \\ V_{3,mx}=-2V_{1,m+1}-2qV_{1m}+2V_{2m}, \\ V_{4,mx}=-2V_{6,m+1}-2qV_{6m}+2rV_{5m}+2u_{2}V_{2m}, \\ V_{5,mx}=2V_{6m}-2u_{2}V_{1m}+2u_{1}V_{3m}-2rV_{4m}, \\ V_{6,mx}=-2V_{4,m+1}-2qV_{4m}+2V_{5m}+2u_{1}V_{2m}, \\ V_{7,mx}=-2V_{9,m+1}-2qV_{9m}+2rV_{8m}+2s_{2}V_{2m}+2s_{2}V_{8m}, \\ V_{8,mx}=2V_{9m}-2s_{2}V_{1m}+2s_{1}V_{3m}-2rV_{7m}+2s_{1}V_{9m}-2s_{2}V_{7m}, \\ V_{9,mx}=-2V_{7,m+1}-2qV_{7m}+2V_{8m}+2s_{1}V_{2m}+2s_{1}V_{8m}. \end{cases} $$

(3.19)

Setting

$$\begin{aligned} V_{+}^{(n)} =&\sum_{m=0}^{n} \bigl(V_{1m}f_{1}(n-m)+V_{2m}f_{2}(n-m)+V_{3m}f_{3}(n-m)+V_{4m}f_{4}(n-m) \\ &{}+V_{5m}f_{5}(n-m)+V_{6m}f_{6}(n-m)+V_{7m}f_{7}(n-m)+V_{8m}f_{8}(n-m)+V_{9m}f_{9}(n-m) \bigr), \end{aligned}$$

we have

$$\begin{aligned}& -V_{+x}^{(n)}+\bigl[U,V_{+}^{(n)}\bigr] \\& \quad =2V_{3,n+1}f_{1}(0)+2V_{1,n+1}f_{3}(0)+2V_{6,n+1}f_{4}(0) \\& \qquad {}+2V_{4,n+1}f_{6}(0)+2V_{9,n+1}f_{7}(0)+2V_{7,n+1}f_{9}(0). \end{aligned}$$

Taking $V^{(n)}=V_{+}^{(n)}-\frac{1}{r}V_{3,n+1}f_{2}(0)$, we obtain

$$\begin{aligned} -V_{x}^{(n)}+\bigl[U,V^{(n)}\bigr] =&\biggl( \frac{1}{r}V_{3,n+1}\biggr)_{x}f_{2}(0)- \frac {1}{r}V_{2,n+1x}f_{3}(0)+\biggl(2V_{6,n+1}-2 \frac {u_{2}}{r}V_{3,n+1}\biggr)f_{4}(0) \\ &{}+\biggl(2V_{4,n+1}-2 \frac{u_{1}}{r}V_{3,n+1}\biggr)f_{6}(0)+\biggl(2V_{9,n+1}-2\frac{s_{2}}{r}V_{3,n+1} \biggr)f_{7}(0) \\ &{}+\biggl(2V_{7,n+1}-2\frac {s_{1}}{r}V_{3,n+1} \biggr)f_{9}(0). \end{aligned}$$

Thus, the zero curvature equation

$$ U_{t}-V_{x}^{(n)}+ \bigl[U,V^{(n)}\bigr]=0 $$

(3.20)

admits the Lax integrable hierarchy

u_{t} = {(\begin{array}{c} q \\ r \\ u_{1} \\ u_{2} \\ s_{1} \\ s_{2} \end{array})}_{t} = (\begin{array}{c} - {(\frac{1}{r} V_{3, n + 1})}_{x} \\ \frac{1}{r} V_{2, n + 1 x} \\ - 2 V_{6, n + 1} + 2 \frac{u_{2}}{r} V_{3, n + 1} \\ - 2 V_{4, n + 1} + 2 \frac{u_{1}}{r} V_{3, n + 1} \\ - 2 V_{9, n + 1} + 2 \frac{s_{2}}{r} V_{3, n + 1} \\ - 2 V_{7, n + 1} + 2 \frac{s_{1}}{r} V_{3, n + 1} \end{array}) .

(3.21)

When we take $s_{1}=s_{2}=0$ and $u_{1}=u_{2}=0$ in (3.21), respectively, we get two integrable coupling of the generalized coupled Burgers equation hierarchy

u_{t} = {(\begin{array}{c} q \\ r \\ u_{1} \\ u_{2} \end{array})}_{t} = (\begin{array}{c} - {(\frac{1}{r} V_{3, n + 1})}_{x} \\ \frac{1}{r} V_{2, n + 1 x} \\ - 2 V_{6, n + 1} + 2 \frac{u_{2}}{r} V_{3, n + 1} \\ - 2 V_{4, n + 1} + 2 \frac{u_{1}}{r} V_{3, n + 1} \end{array}),

(3.22)

u_{t} = {(\begin{array}{c} q \\ r \\ s_{1} \\ s_{2} \end{array})}_{t} = (\begin{array}{c} - {(\frac{1}{r} V_{3, n + 1})}_{x} \\ \frac{1}{r} V_{2, n + 1 x} \\ - 2 V_{9, n + 1} + 2 \frac{s_{2}}{r} V_{3, n + 1} \\ - 2 V_{7, n + 1} + 2 \frac{s_{1}}{r} V_{3, n + 1} \end{array}) .

(3.23)

So we call (3.21) the third type of coupling integrable couplings of the generalized coupled Burgers equation hierarchy.

Set $V_{1,0}=0$, $V_{2,0}=\beta $, $V_{3,0}=V_{4,0}=V_{5,0}=V_{6,0}=V_{7,0}=V_{8,0}=V_{9,0}=0$, we can obtain $V_{1,1}=\beta$, $V_{2,1}=0$, $V_{3,1}=\beta r$, $V_{4,1}=\beta u_{1}$, $V_{5,1}=0$, $V_{6,1}=\beta u_{2} $, $V_{7,1}=\beta s_{1}$, $V_{8,1}=0$, $V_{9,1}=\beta s_{2} , \ldots$ .

And when we take $n=2$ in (3.21), we get the third hind of the coupling integrable couplings of the generalized coupled Burgers equation, that is,

$$ \textstyle\begin{cases} q_{t}=-\beta(\frac{r_{xx}}{4r}+\frac{q_{x}}{r}+q^{2}+\frac {r^{2}}{2})_{x}, \\ r_{t}=\beta(\frac{r_{xx}}{2r}+\frac{q_{x}}{r}-q_{x}r-2qr_{x}), \\ u_{1t}=-\frac{\beta}{2}u_{2xx}-2\beta u_{1x}q-\beta u_{1}q_{x}+2\beta u_{1}r-2\beta u_{2}r^{2}+\frac{\beta}{2} \frac{u_{2}r_{xx}}{r}+\beta \frac{u_{2}q_{x}}{r}, \\ u_{2t}=-\frac{\beta}{2}u_{1xx}-2\beta u_{2x}q-\beta u_{2}q_{x}+2\beta u_{1}-2\beta u_{2}r+\frac{\beta}{2} \frac{u_{1}r_{xx}}{r}+\beta \frac {u_{1}q_{x}}{r}, \\ s_{1t}=-\frac{\beta}{2}s_{2xx}-2\beta s_{1x}q-\beta s_{1}q_{x}+2\beta s_{1}r-2\beta s_{2}r^{2}-3\beta s_{2}^{2}r+\beta s_{1}^{2}r+2\beta s_{1}s_{2} \\ \hphantom{s_{1t}={}}{}-\beta s_{2}^{3}+\beta s_{1}^{2}s_{2}+\frac{\beta}{2} \frac {s_{2}r_{xx}}{r}+\beta\frac{s_{2}q_{x}}{r}, \\ s_{2t}=-\frac{\beta}{2}s_{1xx}-2\beta s_{2x}q-\beta s_{2}q_{x}+2\beta s_{1}-2\beta s_{2}r+3\beta s_{1}^{2}r-\beta s_{2}^{2}-2\beta s_{1}s_{2}r \\ \hphantom{s_{2t}={}}{}+\beta s_{1}^{3}-\beta s_{1}s_{2}^{2}+\frac{\beta}{2} \frac{s_{1}r_{xx}}{r}+\beta\frac{s_{1}q_{x}}{r}. \end{cases} $$

(3.24)

Similarly when take $u_{1}=u_{2}=s_{1}=s_{2}=0$, $n=2$, $\alpha=-2$ in (3.24), we can obtain (3.10).

4 Hamiltonian structure of coupling integrable couplings of the generalized coupled Burgers equation hierarchy

In this section we shall deduce the Hamiltonian forms of the coupling integrable couplings (3.21) by using the quadratic-form [39]. The commutator (2.4) can be written as

$$ [a,b]^{T}=a^{T}R(b), $$

(4.1)

where

\begin{matrix} R (b) \\ = (\begin{array}{c} 0 & 2 b_{3} & 2 b_{2} & 0 & 2 b_{6} & 2 b_{5} & 0 & 2 b_{9} & 2 b_{8} \\ - 2 b_{3} & 0 & - 2 b_{1} & - 2 b_{6} & 0 & - 2 b_{4} & - 2 b_{9} & 0 & - 2 b_{7} \\ 2 b_{2} & - 2 b_{1} & 0 & 2 b_{5} & - 2 b_{4} & 0 & 2 b_{8} & - 2 b_{7} & 0 \\ 0 & 0 & 0 & 0 & 2 b_{3} & 2 b_{2} & 0 & 0 & 0 \\ 0 & 0 & 0 & - 2 b_{3} & 0 & - 2 b_{1} & 0 & 0 & 0 \\ 0 & 0 & 0 & 2 b_{2} & - 2 b_{1} & 0 & 0 & 0 & 0 \\ 0 & 0 & 0 & 0 & 0 & 0 & 0 & 2 b_{3} + 2 b_{9} & 2 b_{2} + 2 b_{8} \\ 0 & 0 & 0 & 0 & 0 & 0 & - 2 b_{3} - 2 b_{9} & 0 & - 2 b_{1} - 2 b_{7} \\ 0 & 0 & 0 & 0 & 0 & 0 & 2 b_{2} + 2 b_{8} & - 2 b_{1} - 2 b_{7} & 0 \end{array}) . \end{matrix}

(4.2)

The constant symmetric matrix F satisfying the matrix equation

$$ R(b)F=-\bigl(R(b)F\bigr)^{T},\qquad F=F^{T}, $$

(4.3)

shows that

F = (\begin{array}{c} 1 & 0 & 0 & 1 & 0 & 0 & 1 & 0 & 0 \\ 0 & 1 & 0 & 0 & 1 & 0 & 0 & 1 & 0 \\ 0 & 0 & - 1 & 0 & 0 & - 1 & 0 & 0 & - 1 \\ 1 & 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \\ 0 & 1 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \\ 0 & 0 & - 1 & 0 & 0 & 0 & 0 & 0 & 0 \\ 1 & 0 & 0 & 0 & 0 & 0 & 1 & 0 & 0 \\ 0 & 1 & 0 & 0 & 0 & 0 & 0 & 1 & 0 \\ 0 & 0 & - 1 & 0 & 0 & 0 & 0 & 0 & - 1 \end{array}) .

(4.4)

In the linear space $R^{9}$, define a functional,

$$\begin{aligned} \{a,b\} =&a^{T}Fb \\ =&a_{1}b_{1}+a_{2}b_{2}-a_{3}b_{3}+a_{7}b_{7} \\ &{}+a_{8}b_{8}-a_{9}b_{9}+(a_{1}b_{4}+a_{4}b_{1})+(a_{1}b_{7}+a_{7}b_{1})+(a_{2}b_{5}+a_{5}b_{2}) \\ &{}+(a_{2}b_{8}+a_{8}b_{2})-(a_{3}b_{6}+a_{6}b_{3})-(a_{3}b_{9}+a_{9}b_{3}). \end{aligned}$$

(4.5)

The Lax pair U and V in (3.18) can be written as

$$ \textstyle\begin{cases} U=(1,q+\lambda,r,u_{1},0,u_{2},s_{1},0,s_{2})^{T}, \\ V=(V_{1},V_{2},V_{3},V_{4},V_{5},V_{6},V_{7},V_{8},V_{9}), \end{cases} $$

(4.6)

where $V_{i}=\sum_{m\geq0}V_{im}\lambda^{-m}$, $i=1,2,\ldots,9$. With the help of (4.2), we have

$$\begin{aligned}& \biggl\{ V,\frac{\partial U}{\partial\lambda}\biggr\} =V_{2}+V_{5}+V_{8}, \\& \biggl\{ V,\frac{\partial U}{\partial q}\biggr\} =V_{2}+V_{5}+V_{8}, \\& \biggl\{ V,\frac{\partial U}{\partial r}\biggr\} =-V_{3}-V_{6}-V_{9}, \\& \biggl\{ V,\frac{\partial U}{\partial u_{1}}\biggr\} =V_{1},\qquad \biggl\{ V, \frac{\partial U}{\partial u_{2}}\biggr\} =-V_{3}, \\& \biggl\{ V,\frac{\partial U}{\partial s_{1}}\biggr\} =V_{1}+V_{7},\qquad \biggl\{ V, \frac {\partial U}{\partial s_{2}}\biggr\} =-V_{3}-V_{9}, \end{aligned}$$

substituting the above into the quadratic-form identity yields

\frac{δ}{δ \overline{u}} (V_{2} + V_{5} + V_{8}) = λ^{- γ} \frac{\partial}{\partial λ} λ^{γ} (\begin{array}{c} V_{2} + V_{5} + V_{8} \\ - V_{3} - V_{6} - V_{9} \\ V_{1} \\ - V_{3} \\ V_{1} + V_{7} \\ - V_{3} - V_{9} \end{array}),

(4.7)

where

\frac{δ}{δ u} = (\begin{array}{c} \frac{δ}{δ q} \\ \frac{δ}{δ r} \\ \frac{δ}{δ u_{1}} \\ \frac{δ}{δ u_{2}} \\ \frac{δ}{δ s_{1}} \\ \frac{δ}{δ s_{2}} \end{array}) .

Comparing the coefficients of $\lambda^{-n-2}$ on both sides of (4.7), we get

\frac{δ}{δ \overline{u}} (V_{2, n + 2} + V_{5, n + 2} + V_{8, n + 2}) = (γ - n - 1) (\begin{array}{c} V_{2, n + 1} + V_{5, n + 1} + V_{8, n + 1} \\ - V_{3, n + 1} - V_{6, n + 1} - V_{9, n + 1} \\ V_{1, n + 1} \\ - V_{3, n + 1} \\ V_{1, n + 1} + V_{7, n + 1} \\ - V_{3, n + 1} - V_{9, n + 1} \end{array}) .

(4.8)

Taking $n=0$ in (4.8), we obtain $\gamma=0$.

So we get

\frac{δ H_{n + 2}}{δ u} = (\begin{array}{c} V_{2, n + 1} + V_{5, n + 1} + V_{8, n + 1} \\ - V_{3, n + 1} - V_{6, n + 1} - V_{9, n + 1} \\ V_{1, n + 1} \\ - V_{3, n + 1} \\ V_{1, n + 1} + V_{7, n + 1} \\ - V_{3, n + 1} - V_{9, n + 1} \end{array}),

(4.9)

where

$$H_{n+2}=-\frac{V_{2,n+2}+V_{5,n+2}+V_{8,n+2}}{n+1}. $$

So (3.21) can be written as a Hamiltonian form

\begin{array}{rcl} u_{t} & = & {(\begin{array}{c} q \\ r \\ u_{1} \\ u_{2} \\ s_{1} \\ s_{2} \end{array})}_{t} = (\begin{array}{c} - {(\frac{1}{r} V_{3, n + 1})}_{x} \\ \frac{1}{r} V_{2, n + 1 x} \\ - 2 V_{6, n + 1} + 2 \frac{u_{2}}{r} V_{3, n + 1} \\ - 2 V_{4, n + 1} + 2 \frac{u_{1}}{r} V_{3, n + 1} \\ - 2 V_{9, n + 1} + 2 \frac{s_{2}}{r} V_{3, n + 1} \\ - 2 V_{7, n + 1} + 2 \frac{s_{1}}{r} V_{3, n + 1} \end{array}) \\ = & (\begin{array}{c} 0 & 0 & 0 & \partial \frac{1}{r} & 0 & 0 \\ 0 & 0 & - 2 & - \frac{2}{r} & 0 & 0 \\ 0 & 2 & 0 & - 2 \frac{u_{2}}{r} & 0 & - 2 \\ \frac{1}{r} \partial & \frac{2}{r} & 2 \frac{u_{2}}{r} & 0 & 2 + 2 \frac{s_{2}}{r} & 2 \frac{s_{1}}{r} \\ 0 & 0 & 0 & - 2 - 2 \frac{s_{2}}{r} & 0 & 2 \\ 0 & 0 & 2 & - 2 \frac{s_{1}}{r} & - 2 & 0 \end{array}) \\ \times (\begin{array}{c} V_{2, n + 1} + V_{5, n + 1} + V_{8, n + 1} \\ - V_{3, n + 1} - V_{6, n + 1} - V_{9, n + 1} \\ V_{1, n + 1} \\ - V_{3, n + 1} \\ V_{1, n + 1} + V_{7, n + 1} \\ - V_{3, n + 1} - V_{9, n + 1} \end{array}) \\ = & J \frac{δ H_{n + 2}}{δ u}, \end{array}

(4.10)

where $\partial=\frac{\partial}{\partial x}$ and J is a Hamiltonian operator. We can obtain a recursive operator from (3.19),

L = (\begin{array}{c} l_{11} & l_{12} & l_{13} & l_{14} & l_{15} & l_{16} \\ l_{21} & l_{22} & l_{23} & l_{24} & l_{25} & l_{26} \\ l_{31} & l_{32} & l_{33} & l_{34} & l_{35} & l_{36} \\ l_{41} & l_{42} & l_{43} & l_{44} & l_{45} & l_{46} \\ l_{51} & l_{52} & l_{53} & l_{54} & l_{55} & l_{56} \\ l_{61} & l_{62} & l_{63} & l_{64} & l_{65} & l_{66} \end{array}),

(4.11)

where

$$\begin{aligned}& l_{11}=\frac{1}{2r}\partial-\partial^{-1}q\partial, \qquad l_{12}=\frac {1}{r}\partial-\partial^{-1}r \partial,\qquad l_{13}=\frac {u_{2}}{r}\partial - \partial^{-1}u_{1}\partial, \\& l_{14}= \frac{u_{1}}{r}\partial -\partial ^{-1}u_{2}\partial ,\qquad l_{15}=\frac{s_{2}}{r}\partial-\partial^{-1}s_{1} \partial ,\qquad l_{16}=\frac {s_{1}}{r}\partial- \partial^{-1}s_{2}\partial , \\& l_{21}=-r-\frac{1}{4}\partial\frac{1}{r}\partial,\qquad l_{22}=-q-\frac {1}{2}\partial\frac{1}{r}, \qquad l_{23}=2u_{2}\partial^{-1}r-\frac {1}{2} \partial\frac{u_{2}}{r},\qquad l_{24}=-\frac{1}{2}\partial \frac {u_{1}}{r} , \\& l_{25}=2s_{2}\partial^{-1}r+2s_{2} \partial^{-1}s_{2}-\frac {1}{2}\partial \frac{s_{2}}{r},\qquad l_{26}=-\frac{1}{2}\partial \frac {s_{1}}{r}+2s_{2}\partial^{-1}+2s_{2} \partial^{-1}s_{1} , \\& l_{31}=l_{32}=l_{35}=l_{36}=0,\qquad l_{33}=-q-2\partial^{-1}r,\qquad l_{34}= \frac {\partial}{2}-2\partial^{-1} , \\& l_{41}=l_{42}=l_{45}=l_{46}=0,\qquad l_{43}=\frac{\partial}{2}+2r\partial ^{-1}r,\qquad l_{34}=2r\partial^{-1}-q , \\& l_{51}=l_{52}=l_{53}=l_{54}=0,\qquad l_{55}=-q-2\partial^{-1}r-2\partial ^{-1}s_{2}-2s_{1} \partial^{-1}r-2s_{1}\partial^{-1}s_{2} , \\& l_{56}=\frac{1}{2}\partial-2\partial^{-1}-2\partial ^{-1}s_{1}-2s_{1}\partial^{-1}-2s_{1} \partial^{-1}s_{1} , \\& l_{61}=l_{62}=l_{63}=l_{64}=0,\qquad l_{65}=\frac{1}{2}\partial+2r\partial ^{-1}r+2r \partial^{-1}s_{2}+2s_{2}\partial^{-1}r+2s_{2} \partial ^{-1}s_{2} , \\& l_{66}=-q+2r\partial^{-1}+2r\partial^{-1}s_{1}+2s_{2} \partial ^{-1}+2s_{2}\partial^{-1}s_{1} . \end{aligned}$$

L satisfies

(\begin{array}{c} V_{2, n + 1} + V_{5, n + 1} + V_{8, n + 1} \\ - V_{3, n + 1} - V_{6, n + 1} - V_{9, n + 1} \\ V_{1, n + 1} \\ - V_{3, n + 1} \\ V_{1, n + 1} + V_{7, n + 1} \\ - V_{3, n + 1} - V_{9, n + 1} \end{array}) = L (\begin{array}{c} V_{2 n} + V_{5 n} + V_{8 n} \\ - V_{3 n} - V_{6 n} - V_{9 n} \\ V_{1 n} \\ - V_{3 n} \\ V_{1 n} + V_{7 n} \\ - V_{3 n} - V_{9 n} \end{array}) .

The Hamiltonian form of the coupling integrable couplings (3.21) can be written as

u_{t} = J \frac{δ H_{n + 2}}{δ u} = J L^{n} (\begin{array}{c} 0 \\ - β r - β u_{2} - β s_{2} \\ β \\ - β r \\ β + β s_{1} \\ - β r - β s_{2} \end{array}) .

(4.12)

5 Conclusion

In this paper we get three kinds of coupling integrable couplings of the generalized coupled Burgers equation hierarchy, which are new results. And we obtain the Hamiltonian structure of one coupling integrable couplings of the generalized coupled Burgers equation hierarchy by using the quadratic-form identity.

6 Results and discussion

Firstly, we introduce three Lie algebras E, F and H. With the help of their corresponding loop algebras Ẽ, F̃, and H̃, we establish three isospectral problems, respectively. Then, by taking advantage of the Tu scheme, we get three kinds of coupling integrable couplings of the generalized coupled Burgers equation hierarchy as follows:

$$\begin{aligned}& \textstyle\begin{cases} q_{t}=-\beta(\frac{r_{xx}}{4r}+\frac{q_{x}}{r}+q^{2}+\frac {r^{2}}{2})_{x}, \\ r_{t}=\beta(\frac{r_{xx}}{2r}+\frac{q_{x}}{r}-q_{x}r-2qr_{x}), \\ u_{1t}=-\frac{\beta}{2}u_{2xx}-2\beta u_{1x}q-\beta u_{1}q_{x}+2\beta u_{1}r-2\beta u_{2}r^{2}+\frac{\beta}{2} \frac{u_{2}r_{xx}}{r}+\beta \frac{u_{2}q_{x}}{r}, \\ u_{2t}=-\frac{\beta}{2}u_{1xx}-2\beta u_{2x}q-\beta u_{2}q_{x}+2\beta u_{1}-2\beta u_{2}r+\frac{\beta}{2} \frac{u_{1}r_{xx}}{r}+\beta \frac {u_{1}q_{x}}{r}, \\ s_{1t}=-\frac{\beta}{2}s_{2xx}-2\beta s_{1x}q-\beta s_{1}q_{x}+2\beta s_{1}r-2\beta s_{2}r^{2}-3\beta s_{2}^{2}r+\beta s_{1}^{2}r+2\beta s_{1}s_{2} \\ \hphantom{s_{1t}={}}{}-\beta s_{2}^{3}+\beta s_{1}^{2}s_{2}+\frac{\beta}{2} \frac {s_{2}r_{xx}}{r}+\beta\frac{s_{2}q_{x}}{r}, \\ s_{2t}=-\frac{\beta}{2}s_{1xx}-2\beta s_{2x}q-\beta s_{2}q_{x}+2\beta s_{1}-2\beta s_{2}r+3\beta s_{1}^{2}r-\beta s_{2}^{2}-2\beta s_{1}s_{2}r+\beta s_{1}^{3} \\ \hphantom{s_{2t}={}}{}-\beta s_{1}s_{2}^{2}+\frac{\beta}{2} \frac{s_{1}r_{xx}}{r}+\beta\frac{s_{1}q_{x}}{r}, \end{cases}\displaystyle \end{aligned}$$

(6.1)

$$\begin{aligned}& \textstyle\begin{cases} q_{t}=-\beta(\frac{r_{xx}}{4r}+\frac{q_{x}}{r}+q^{2}+\frac {r^{2}}{2})_{x}, \\ r_{t}=\beta(\frac{r_{xx}}{2r}+\frac{q_{x}}{r}-q_{x}r-2qr_{x}), \\ u_{1t}=\beta u_{2xx}-2\beta u_{1x}q-\beta u_{1}q_{x}-\beta u_{2x}-\frac {\beta}{2}u_{1}r_{x}-\beta u_{1x}r-\beta\frac{u_{2}r_{xx}}{4r}-\beta \frac{u_{2}q_{x}}{2r}, \\ u_{2t}=\beta u_{1xx}-2\beta u_{2x}q-\beta u_{2}q_{x}+\beta u_{1x}+\frac {\beta}{2}u_{2}r_{x}+\beta u_{2x}r-\beta\frac{u_{1}r_{xx}}{4r}-\beta \frac{u_{1}q_{x}}{2r}, \\ s_{1t}=\beta s_{2xx}-2\beta s_{1x}q-\beta s_{1}q_{x}-\beta s_{2x}-\frac {\beta}{2}s_{1}r_{x}-\beta s_{1x}r-\beta\frac{s_{2}r_{xx}}{4r}-\beta \frac{s_{2}q_{x}}{2r}, \\ s_{2t}=\beta s_{1xx}-2\beta s_{2x}q-\beta s_{2}q_{x}+\beta s_{1x}+\frac {\beta}{2}s_{2}r_{x}+\beta s_{2x}r-\beta\frac{s_{1}r_{xx}}{4r}-\beta \frac{s_{1}q_{x}}{2r}, \end{cases}\displaystyle \end{aligned}$$

(6.2)

$$\begin{aligned}& \textstyle\begin{cases} q_{t}=-\beta(\frac{r_{xx}}{4r}+\frac{q_{x}}{r}+q^{2}+\frac {r^{2}}{2})_{x}, \\ r_{t}=\beta(\frac{r_{xx}}{2r}+\frac{q_{x}}{r}-q_{x}r-2qr_{x}), \\ u_{1t}=-\frac{\beta}{2}s_{1xx}-2\beta u_{1x}q-\beta u_{1}q_{x}+2\beta u_{1}r-2\beta s_{1}r^{2}+\frac{\beta}{2} \frac{s_{1}r_{xx}}{r}+\beta \frac{s_{1}q_{x}}{r}, \\ u_{2t}=-\frac{\beta}{2}s_{2xx}-2\beta u_{2x}q-\beta u_{2}q_{x}+2\beta u_{2}r-2\beta s_{2}r^{2}+\frac{\beta}{2} \frac{s_{2}r_{xx}}{r}+\beta \frac{s_{2}q_{x}}{r}, \\ s_{1t}=-\frac{\beta}{2}u_{1xx}-2\beta s_{1x}q-\beta s_{1}q_{x}+2\beta u_{1}-2\beta s_{1}r+\frac{\beta}{2} \frac{u_{1}r_{xx}}{r}+\beta \frac {u_{1}q_{x}}{r}, \\ s_{2t}=-\frac{\beta}{2}u_{2xx}-2\beta s_{2x}q-\beta s_{2}q_{x}+2\beta u_{2}-2\beta s_{2}r+\frac{\beta}{2} \frac{u_{2}r_{xx}}{r}+\beta \frac {u_{2}q_{x}}{r}, \end{cases}\displaystyle \end{aligned}$$

(6.3)

$$\begin{aligned}& \textstyle\begin{cases} q_{t}=-\beta(\frac{r_{xx}}{4r}+\frac{q_{x}}{r}+q^{2}+\frac {r^{2}}{2})_{x}, \\ r_{t}=\beta(\frac{r_{xx}}{2r}+\frac{q_{x}}{r}-q_{x}r-2qr_{x}), \\ u_{1t}=-\frac{\beta}{2}u_{2xx}-2\beta u_{1x}q-\beta u_{1}q_{x}+2\beta u_{1}r-2\beta u_{2}r^{2}+\frac{\beta}{2} \frac{u_{2}r_{xx}}{r}+\beta \frac{u_{2}q_{x}}{r}, \\ u_{2t}=-\frac{\beta}{2}u_{1xx}-2\beta u_{2x}q-\beta u_{2}q_{x}+2\beta u_{1}-2\beta u_{2}r+\frac{\beta}{2} \frac{u_{1}r_{xx}}{r}+\beta \frac {u_{1}q_{x}}{r}, \\ s_{1t}=-\frac{\beta}{2}s_{2xx}-2\beta s_{1x}q-\beta s_{1}q_{x}+2\beta s_{1}r-2\beta s_{2}r^{2}-3\beta s_{2}^{2}r+\beta s_{1}^{2}r+2\beta s_{1}s_{2} \\ \hphantom{s_{1t}={}}{}-\beta s_{2}^{3}+\beta s_{1}^{2}s_{2}+\frac{\beta}{2} \frac {s_{2}r_{xx}}{r}+\beta\frac{s_{2}q_{x}}{r}, \\ s_{2t}=-\frac{\beta}{2}s_{1xx}-2\beta s_{2x}q-\beta s_{2}q_{x}+2\beta s_{1}-2\beta s_{2}r+3\beta s_{1}^{2}r-\beta s_{2}^{2}-2\beta s_{1}s_{2}r+\beta s_{1}^{3} \\ \hphantom{s_{2t}={}}{}-\beta s_{1}s_{2}^{2}+\frac{\beta}{2} \frac{s_{1}r_{xx}}{r}+\beta\frac{s_{1}q_{x}}{r}. \end{cases}\displaystyle \end{aligned}$$

(6.4)

Finally, we obtain the Hamiltonian structure of one of coupling integrable couplings of the generalized coupled Burgers equation hierarchy by using the quadratic-form identity as follows:

u_{t} = J \frac{δ H_{n + 2}}{δ u} = J L^{n} (\begin{array}{c} 0 \\ - β r - β u_{2} - β s_{2} \\ β \\ - β r \\ β + β s_{1} \\ - β r - β s_{2} \end{array}) .

(6.5)

In this paper we can only get the Hamiltonian structure of one of the coupling integrable couplings of the generalized coupled Burgers equation hierarchy by using the quadratic-form identity. How to get all the Hamiltonian structure of one coupling integrable couplings of the generalized coupled Burgers equation hierarchy is worthy of further studying.

7 Methods and experiment

Not applicable.

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Acknowledgements

The authors are grateful to the anonymous referees and the editor for their careful corrections and valuable comments on the original version of this paper.

Funding

The authors were supported by National Natural Science Foundation of China (Grant Nos. 11701320, 11705122), the Science and Technology Foundations of Shandong Province (Grant Nos. J16li52 and J14li54) and Science Foundations of Binzhou University (Grant Nos. BZXYL1104 and BZXYL1704).

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College of Science, Binzhou University, Binzhou City, P.R. China
Yuan Wei & Li Yin
Department of Applied Mathematics, Changsha University of Science and Technology, Changsha, P.R. China
Xin Long
Hunan Provincial Key Laboratory of Mathematical Modeling and Analysis in Engineering, Changsha, P.R. China
Xin Long

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Wei, Y., Yin, L. & Long, X. The coupling integrable couplings of the generalized coupled Burgers equation hierarchy and its Hamiltonian structure. Adv Differ Equ 2019, 58 (2019). https://doi.org/10.1186/s13662-019-2004-9

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Received: 28 October 2018
Accepted: 31 January 2019
Published: 12 February 2019
DOI: https://doi.org/10.1186/s13662-019-2004-9

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35B06

The coupling integrable couplings of the generalized coupled Burgers equation hierarchy and its Hamiltonian structure

Abstract

1 Introduction

2 Three higher-dimensional Lie algebras

3 Three kinds of coupling integrable couplings of the generalized coupled Burgers equation hierarchy

4 Hamiltonian structure of coupling integrable couplings of the generalized coupled Burgers equation hierarchy

5 Conclusion

6 Results and discussion

7 Methods and experiment

References

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