约当三系上非零权的相对Rota-Baxter算子

doi:10.12677/AAM.2023.125249

期刊菜单

约当三系上非零权的相对Rota-Baxter算子
Relative Rota-Baxter Operator of Non-Zero Weights on the Jordan Triple

DOI: 10.12677/AAM.2023.125249, PDF, HTML, XML,
作者: 史新颖：辽宁师范大学数学学院，辽宁大连
关键词: 约当三系；相对Rota-Baxter算子；作用；伴随表示；Jordan Triple； Relative Rota-Baxter Operator； Action； Adjoint Representation

摘要: 本文主要研究约当三系上关于非零权的相对Rota-Baxter算子。首先回顾了约当代数，约旦三系以及子系的概念，然后给出了约当三系的表示的定义，进而得出约当三系在另一个约当三系上作用的概念，以及约当三系上非零权的相对Rota-Baxter算子的定义，找到了在约当三系及其作用空间的直和上构造新约当三系的方法。最后，给出了在一个约当三系上定义与相对Rota-Baxter算子有关的新运算可得到新的约当三系的方法，并且构造了新的约当三系的表示。此外文中还给出了约当三系上构造相对Rota-Baxter算子的方法。

Abstract: In this paper, we mainly study the relative Rota-Baxter operators on Jordan triple systems of non-zero weights. First, we recall the concepts of Jordan algebra, Jordan triple systems, and subsystems, and then the definition of the representation of Jordan triple systems is given. Then, the concept of Jordan triple systems acting on another Jordan triple system is obtained, as well as the definition of relative Rota-Baxter operators of nonzero weights on Jordan triple systems. A method for con-structing a new Jordan triple system on the direct sum of Jordan triple systems and their action spaces is found. Finally, it is shown that by defining new operations related to the relative Ro-ta-Baxter operator on a Jordan triple system, a new Jordan triple system can be obtained, and a new representation of the Jordan triple system is constructed. In addition, a method for constructing relative Rota-Baxter operators is also presented.

文章引用：史新颖. 约当三系上非零权的相对Rota-Baxter算子[J]. 应用数学进展, 2023, 12(5): 2468-2479. https://doi.org/10.12677/AAM.2023.125249

1. 引言

约当三系的定义最早是1949年由Nathan Jacobson提出的 [1] ，通过约当代数可以构造出约当三系。而约当代数理论最早是有量子物理学的潜在研究所激发的，在物理，特别是量子力学中起着重要的作用。对于约当三系，可以通过约当三系给出一类对称流形的代数描述，并且，约当三系可以提供几种构造李代数的方法。对于约当三系的研究，前人已经得到了很多结果。例如，在 [2] 中作者利用TKK李代数的上同调研究了约当三系的上同调理论；在 [3] 中作者研究了约当三系的表示，证明了有限维约当三系的通用包络是有限维的，若约当三系是它自身的根基，则约当三系的通用包络是幂零的；在 [4] 中作者研究了特征不为2的域上中心非退化约当三系的非零中心及其等价形式。

相对Rota-Baxter算子是Rota-Baxter算子在结合代数上的相对推广，与O-算子有关，起源于经典Yang-Baxter方程的算子形式。在代数上，可以利用相对Rota-Baxte研究上同调理论，如，在 [5] 中作者研究了李代数上权为1的相对Rota-Baxter算子，构造了它们的上同调理论，并利用第二个上同调群来研究相对Rota-Baxter算子和r-矩阵的无穷小变形。在 [6] 中作者给出了在李三系上的相对Rota-Baxter算子以及上同调理论，并利用第一个上同调群对无穷小变形进行了分类。

2. 预备知识

定义1.1 [7] 设J为线性空间，J上有双线性的代数运算“ $\cdot$ ”： $J \times J \to J$ ，如果满足下列条件

$x \cdot y = y \cdot x$ ，

$((x \cdot x) \cdot y) \cdot x = (x \cdot x) \cdot (y \cdot x)$ ，

$\forall x, y \in J$ ，则称 $(J, \cdot)$ 为约当代数。

定义1.2 [8] 设J为线性空间， ${\cdot, \cdot, \cdot} : J \times J \times J \to J$ 是三线性映射，如果满足下列条件

${x, y, z} = {z, y, x}$ (1.1)

${x, y, {z, u, v}} - {z, u, {x, y, v}} - {{x, y, z}, u, v} + {z, {y, x, u}, v} = 0$ (1.2)

$\forall x, y, z, u, v \in J$ ，则称 $(J, {\cdot, \cdot, \cdot})$ 为约当三系。

例1.1 [8] 设 $(J, \cdot)$ 为约当代数，在J上定义代数运算

${x, y, z} = (x \cdot y) \cdot z + (z \cdot y) \cdot x - (x \cdot z) \cdot y$ ，

$\forall x, y, z \in J$ ，则 $(J, {\cdot, \cdot, \cdot})$ 为约当三系。

定义1.3 [9] 设 $(J, {\cdot, \cdot, \cdot})$ 是约当三系，H为J的子空间，如果H满足 ${H, H, H} \subseteq H$ ，则称H是J的子系。

3. 相对Rota-Baxter算子

定义2.1 设 $(J, {\cdot, \cdot, \cdot})$ 是约当三系，V是线性空间， $θ_{12}, θ_{13} : J \times J \to E n d (V)$ 是双线性映射，若 $θ_{12}, θ_{13}$ 满足

$θ_{13} (a, b) = θ_{13} (b, a)$ ， (2.1)

$θ_{12} (x, y) θ_{12} (a, b) - θ_{12} (a, b) θ_{12} (x, y) - θ_{12} ({x, y, a}, b) + θ_{12} (a, {y, x, b}) = 0$ ， (2.2)

$θ_{12} (x, y) θ_{13} (a, b) + θ_{13} (a, b) θ_{12} (y, x) - θ_{13} (a, {x, y, b}_{1}) - θ_{13} ({x, y, a}_{1}, b) = 0$ ， (2.3)

$θ_{12} ({x, a, b}, y) - θ_{12} (x, a) θ_{12} (b, y) - θ_{12} (b, a) θ_{12} (x, y) + θ_{13} (x, b) θ_{13} (a, y) = 0$ ， (2.4)

$θ_{13} ({x, a, b}, y) - θ_{12} (x, a) θ_{13} (b, y) - θ_{12} (b, a) θ_{13} (x, y) + θ_{13} (x, b) θ_{12} (a, y) = 0$ ， (2.5)

$\forall a, b, x, y \in J$ ，则 $(θ_{12}, θ_{13}, V)$ 称为J的表示。

例2.1 设 $(J, {\cdot, \cdot, \cdot})$ 是约当三系，定义双线性映射 $σ_{12}, σ_{13} : J \times J \to E n d (J)$ ，其中 $σ_{12} (x, y) z = {x, y, z}$ ， $σ_{13} (x, y) z = {x, z, y} (\forall x, y, z \in J)$ ，则 $(σ_{12}, σ_{13}, J)$ 是J的表示，称为伴随表示。

证：直接验证可知 $(σ_{12}, σ_{13}, J)$ 满足(2.1)-(2.5)式，故 $(σ_{12}, σ_{13}, J)$ 是J的表示。

定义2.2 设 $(J_{1}, {\cdot, \cdot, \cdot}_{1}), (J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系， $(θ_{12}, θ_{13}, J_{2})$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 的表示。若 $\forall x_{1}, y_{1} \in J_{1}, x_{2}, y_{2}, z_{2} \in J_{2}$ ，有

$θ_{12} (x_{1}, y_{1}) z_{2} \in C (J_{2})$ ，

$θ_{13} (x_{1}, y_{1}) z_{2} \in C (J_{2})$ ，

$θ_{12} (x_{1}, y_{1}) {x_{2}, y_{2}, z_{2}}_{2} = 0$ ，

$θ_{13} (x_{1}, y_{1}) {x_{2}, y_{2}, z_{2}}_{2} = 0$ ，

则称 $θ_{12}, θ_{13}$ 为 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的一个作用。这里

$C (J_{2}) = {u \in J_{2} | {u, v, w}_{2} = 0, {v, u, w}_{2} = 0, \forall v, w \in J_{2}}$ 。

设 $(J, {\cdot, \cdot, \cdot})$ 是约当三系，定义 $J^{1} = {J, J, J}$ 。

例2.2 $(J, {\cdot, \cdot, \cdot})$ 是约当三系，如果J满足 $J^{1} \subseteq C (J)$ ，则伴随表示 $(σ_{12}, σ_{13}, J)$ 是J在自身上的一个作用。

证：由例2.1可知，伴随表示 $(σ_{12}, σ_{13}, J)$ 是J的表示。因为 $J^{1} \subseteq C (J)$ ，所以 $\forall x_{1}, x_{2}, x_{3}, x_{4}, x_{5} \in J$ ，

$σ_{12} (x_{1}, x_{2}) x_{3} = {x_{1}, x_{2}, x_{3}} \in C (J)$ ，

$σ_{13} (x_{1}, x_{2}) x_{3} = {x_{1}, x_{3}, x_{2}} \in C (J)$ ，

$σ_{12} (x_{1}, x_{2}) {x_{3}, x_{4}, x_{5}} = {x_{1}, x_{2}, {x_{3}, x_{4}, x_{5}}} = 0$ ，

$σ_{13} (x_{1}, x_{2}) {x_{3}, x_{4}, x_{5}} = {x_{1}, {x_{3}, x_{4}, x_{5}}, x_{2}} = 0$ ，

因此， $σ_{12}, σ_{13}$ 是J在自身上的一个作用。

定义2.3 $(J_{1}, {\cdot, \cdot, \cdot}_{1}), (J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系， $θ_{12}, θ_{13}$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的作用， $T : J_{2} \to J_{1}$ 是线性映射，如果T满足

${T u, T v, T w}_{1} = T (θ_{12} (T w, T v) u + θ_{13} (T u, T w) v + θ_{12} (T u, T v) w + λ {u, v, w}_{2})$ ， (2.6)

$\forall u, v, w \in J_{2}$ ，则T称为关于作用 $θ_{12}, θ_{13}$ 的从 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 到 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 的权为 $λ$ 的相对Rota-Baxter算子。

命题2.1 $(J_{1}, {\cdot, \cdot, \cdot}_{1}), (J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系， $θ_{12}, θ_{13}$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的作用。在 $J_{1} \oplus J_{2}$ 上定义运算 ${\cdot, \cdot, \cdot}_{θ}$ ，其中

${x + u, y + v, z + w}_{θ} = {x, y, z}_{1} + θ_{12} (z, y) u + θ_{13} (x, z) v + θ_{12} (x, y) w + λ {u, v, w}_{2}$ ，

$\forall x, y, z \in J_{1}, u, v, w \in J_{2}$ ，则 $(J_{1} \oplus J_{2}, {\cdot, \cdot, \cdot}_{θ})$ 是约当三系，称为 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 和 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 的半直积。

证：显然，在 $J_{1} \oplus J_{2}$ 上定义的运算对三个变量都是线性的，因此若要证 $(J_{1} \oplus J_{2}, {\cdot, \cdot, \cdot}_{θ})$ 是约当三系，只需在 $J_{1} \oplus J_{2}$ 上验证(1.1)-(1.2)式成立。 $\forall x_{1}, y_{1}, z_{1}, a_{1}, b_{1} \in J_{1}, x_{2}, y_{2}, z_{2}, a_{2}, b_{2} \in J_{2}$ ，直接计算(1.1)式左式得

$\begin{array}{l} {x_{1} + x_{2}, y_{1} + y_{2}, z_{1} + z_{2}}_{θ} - {z_{1} + z_{2}, y_{1} + y_{2}, x_{1} + x_{2}}_{θ} \\ = {x_{1}, y_{1}, z_{1}}_{1} + θ_{13} (x_{1}, z_{1}) y_{2} + θ_{12} (z_{1}, y_{1}) x_{2} + θ_{12} (x_{1}, y_{1}) z_{2} + λ {x_{2}, y_{2}, z_{2}}_{2} \\ - {z_{1}, y_{1}, x_{1}}_{1} - θ_{13} (z_{1}, x_{1}) y_{2} - θ_{12} (x_{1}, y_{1}) z_{2} - θ_{12} (z_{1}, y_{1}) x_{2} - λ {z_{2}, y_{2}, x_{2}}_{2} \end{array}$ ，

由于 $(J_{1}, {\cdot, \cdot, \cdot}_{1}), (J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系且 $θ_{13}$ 是对称的，故在 $J_{1} \oplus J_{2}$ 上(1.1)式成立。

$\begin{array}{l} {x_{1} + x_{2}, y_{1} + y_{2}, {z_{1} + z_{2}, a_{1} + a_{2}, b_{1} + b_{2}}_{θ}}_{θ} - {z_{1} + z_{2}, a_{1} + a_{2}, {x_{1} + x_{2}, y_{1} + y_{2}, b_{1} + b_{2}}_{θ}}_{θ} \\ - {{x_{1} + x_{2}, y_{1} + y_{2}, z_{1} + z_{2}}_{θ}, a_{1} + a_{2}, b_{1} + b_{2}}_{θ} + {z_{1} + z_{2}, {y_{1} + y_{2}, x_{1} + x_{2}, a_{1} + a_{2}}_{θ}, b_{1} + b_{2}}_{θ} \\ = {x_{1} + x_{2}, y_{1} + y_{2}, {z_{1}, a_{1}, b_{1}}_{1} + θ_{13} (z_{1}, b_{1}) a_{2} + θ_{12} (b_{1}, a_{1}) z_{2} + θ_{12} (z_{1}, a_{1}) b_{2} + λ {z_{2}, a_{2}, b_{2}}_{2}}_{θ} \\ - {z_{1} + z_{2}, a_{1} + a_{2}, {x_{1}, y_{1}, b_{1}}_{1} + θ_{13} (x_{1}, b_{1}) y_{2} + θ_{12} (b_{1}, y_{1}) x_{2} + θ_{12} (x_{1}, y_{1}) b_{2} + λ {x_{2}, y_{2}, b_{2}}_{2}}_{θ} \\ - {{x_{1}, y_{1}, z_{1}}_{1} + θ_{13} (x_{1}, z_{1}) y_{2} + θ_{12} (z_{1}, y_{1}) x_{2} + θ_{12} (x_{1}, y_{1}) z_{2} + λ {x_{2}, y_{2}, z_{2}}_{2}, a_{1} + a_{2}, b_{1} + b_{2}}_{θ} \end{array}$

$\begin{array}{l} + {z_{1} + z_{2}, {y_{1}, x_{1}, a_{1}}_{1} + θ_{13} (y_{1}, a_{1}) x_{2} + θ_{12} (a_{1}, x_{1}) y_{2} + θ_{12} (y_{1}, x_{1}) a_{2} + λ {y_{2}, x_{2}, a_{2}}_{2}, b_{1} + b_{2}}_{θ} \\ = {x_{1}, y_{1}, {z_{1}, a_{1}, b_{1}}_{1}}_{1} + θ_{13} (x_{1}, {z_{1}, a_{1}, b_{1}}_{1}) y_{2} + θ_{12} ({z_{1}, a_{1}, b_{1}}_{1}, y_{1}) x_{2} + θ_{12} (x_{1}, y_{1}) θ_{13} (z_{1}, b_{1}) a_{2} \\ + λ {x_{2}, y_{2}, θ_{13} (z_{1}, b_{1}) a_{2}}_{2} + θ_{12} (x_{1}, y_{1}) θ_{12} (b_{1}, a_{1}) z_{2} + λ {x_{2}, y_{2}, θ_{12} (b_{1}, a_{1}) z_{2}}_{2} \\ + θ_{12} (x_{1}, y_{1}) θ_{12} (z_{1}, a_{1}) b_{2} + λ {x_{2}, y_{2}, θ_{12} (z_{1}, a_{1}) b_{2}}_{2} + λ θ_{12} (x_{1}, y_{1}) {z_{2}, a_{2}, b_{2}}_{2} \\ + λ {x_{2}, y_{2}, λ {z_{2}, a_{2}, b_{2}}_{2}}_{2} - {z_{1}, a_{1}, {x_{1}, y_{1}, b_{1}}_{1}}_{1} - θ_{13} (z_{1}, {x_{1}, y_{1}, b_{1}}_{1}) a_{2} \end{array}$

$\begin{array}{l} - θ_{12} ({x_{1}, y_{1}, b_{1}}_{1}, a_{1}) z_{2} - θ_{12} (z_{1}, a_{1}) θ_{13} (x_{1}, b_{1}) y_{2} - λ {z_{2}, a_{2}, θ_{13} (x_{1}, b_{1}) y_{2}}_{2} \\ - θ_{12} (z_{1}, a_{1}) θ_{12} (b_{1}, y_{1}) x_{2} - λ {z_{2}, a_{2}, θ_{12} (b_{1}, y_{1}) x_{2}}_{2} - θ_{12} (z_{1}, a_{1}) θ_{12} (x_{1}, y_{1}) b_{2} \\ - λ {z_{2}, a_{2}, θ_{12} (x_{1}, y_{1}) b_{2}}_{2} - λ θ_{12} (z_{1}, a_{1}) {x_{2}, y_{2}, b_{2}}_{2} - λ {z_{2}, a_{2}, λ {x_{2}, y_{2}, b_{2}}_{2}}_{2} \\ - {{x_{1}, y_{1}, z_{1}}_{1}, a_{1}, b_{1}}_{1} - θ_{13} ({x_{1}, y_{1}, z_{1}}_{1}, b_{1}) a_{2} - θ_{12} ({x_{1}, y_{1}, z_{1}}_{1}, a_{1}) b_{2} \\ - θ_{12} (b_{1}, a_{1}) θ_{13} (x_{1}, z_{1}) y_{2} - λ {θ_{13} (x_{1}, z_{1}) y_{2}, a_{2}, b_{2}}_{2} - θ_{12} (b_{1}, a_{1}) θ_{12} (z_{1}, y_{1}) x_{2} \end{array}$

$\begin{array}{l} - λ {θ_{12} (z_{1}, y_{1}) x_{2}, a_{2}, b_{2}}_{2} - θ_{12} (b_{1}, a_{1}) θ_{12} (x_{1}, y_{1}) z_{2} - λ {θ_{12} (x_{1}, y_{1}) z_{2}, a_{2}, b_{2}}_{2} \\ - λ θ_{12} (b_{1}, a_{1}) {x_{2}, y_{2}, z_{2}}_{2} - λ {λ {x_{2}, y_{2}, z_{2}}_{2}, a_{2}, b_{2}}_{2} + {z_{1}, {y_{1}, x_{1}, a_{1}}_{1}, b_{1}}_{1} \\ + θ_{12} (b_{1}, {y_{1}, x_{1}, a_{1}}_{1}) z_{2} + θ_{12} (z_{1}, {y_{1}, x_{1}, a_{1}}_{1}) b_{2} + θ_{13} (z_{1}, b_{1}) θ_{13} (y_{1}, a_{1}) x_{2} \\ + λ {z_{2}, θ_{13} (y_{1}, a_{1}) x_{2}, b_{2}}_{2} + θ_{13} (z_{1}, b_{1}) θ_{12} (a_{1}, x_{1}) y_{2} + λ {z_{2}, θ_{12} (a_{1}, x_{1}), b_{2}}_{2} \\ + θ_{13} (z_{1}, b_{1}) θ_{12} (y_{1}, x_{1}) a_{2} + λ {z_{2}, θ_{12} (y_{1}, x_{1}) a_{2}, b_{2}}_{2} + λ θ_{13} (z_{1}, b_{1}) {y_{2}, x_{2}, a_{2}}_{2} + λ {z_{2}, λ {y_{2}, x_{2}, a_{2}}_{2}, b_{2}}_{2} \end{array}$

$\begin{array}{l} = ({x_{1}, y_{1}, {z_{1}, a_{1}, b_{1}}_{1}}_{1} - {z_{1}, a_{1}, {x_{1}, y_{1}, b_{1}}_{1}}_{1} - {{x_{1}, y_{1}, z_{1}}_{1}, a_{1}, b_{1}}_{1} + {z_{1}, {y_{1}, x_{1}, a_{1}}_{1}, b_{1}}_{1}) \\ + λ^{2} ({x_{2}, y_{2}, {z_{2}, a_{2}, b_{2}}_{2}}_{2} - {z_{2}, a_{2}, {x_{2}, y_{2}, b_{2}}_{2}}_{2} - {{x_{2}, y_{2}, z_{2}}_{2}, a_{2}, b_{2}}_{2} \\ + {z_{2}, {y_{2}, x_{2}, a_{2}}_{2}, b_{2}}_{2}) + A_{1} x_{2} + A_{2} y_{2} + A_{3} z_{2} + A_{4} a_{2} + A_{5} b_{2} + λ A_{6} \end{array}$

其中，

$A_{1} = θ_{12} ({z_{1}, a_{1}, b_{1}}_{1}, y_{1}) - θ_{12} (z_{1}, a_{1}) θ_{12} (b_{1}, y_{1}) - θ_{12} (b_{1}, a_{1}) θ_{12} (z_{1}, y_{1}) + θ_{13} (z_{1}, b_{1}) θ_{13} (y_{1}, a_{1})$ ，

$A_{2} = θ_{13} (x_{1}, {z_{1}, a_{1}, b_{1}}_{1}) - θ_{12} (z_{1}, a_{1}) θ_{13} (x_{1}, b_{1}) - θ_{12} (b_{1}, a_{1}) θ_{13} (x_{1}, z_{1}) + θ_{13} (z_{1}, b_{1}) θ_{12} (a_{1}, x_{1})$ ，

$A_{3} = θ_{12} (x_{1}, y_{1}) θ_{12} (b_{1}, a_{1}) - θ_{12} ({x_{1}, y_{1}, b_{1}}_{1}, a_{1}) - θ_{12} (b_{1}, a_{1}) θ_{12} (x_{1}, y_{1}) + θ_{12} (b_{1}, {y_{1}, x_{1}, a_{1}}_{1})$ ，

$A_{4} = θ_{12} (x_{1}, y_{1}) θ_{13} (z_{1}, b_{1}) - θ_{13} (z_{1}, {x_{1}, y_{1}, b_{1}}_{1}) - θ_{13} ({x_{1}, y_{1}, z_{1}}_{1}, b_{1}) + θ_{13} (z_{1}, b_{1}) θ_{12} (y_{1}, x_{1})$ ，

$A_{5} = θ_{12} (x_{1}, y_{1}) θ_{12} (z_{1}, a_{1}) - θ_{12} (z_{1}, a_{1}) θ_{12} (x_{1}, y_{1}) - θ_{12} ({x_{1}, y_{1}, z_{1}}_{1}, a_{1}) + θ_{12} (z_{1}, {y_{1}, x_{1}, a_{1}}_{1})$ ，

$\begin{matrix} A_{6} = {x_{2}, y_{2}, θ_{13} (z_{1}, b_{1}) a_{2}}_{2} + {x_{2}, y_{2}, θ_{12} (b_{1}, a_{1}) z_{2}}_{2} + {x_{2}, y_{2}, θ_{12} (z_{1}, a_{1}) b_{2}}_{2} + θ_{12} (x_{1}, y_{1}) {z_{2}, a_{2}, b_{2}}_{2} \\ - {z_{2}, a_{2}, θ_{13} (x_{1}, b_{1}) y_{2}}_{2} - {z_{2}, a_{2}, θ_{12} (b_{1}, y_{1}) x_{2}}_{2} - {z_{2}, a_{2}, θ_{12} (x_{1}, y_{1}) b_{2}}_{2} - θ_{12} (z_{1}, a_{1}) {x_{2}, y_{2}, b_{2}}_{2} \\ - {θ_{13} (x_{1}, z_{1}) y_{2}, a_{2}, b_{2}}_{2} - {θ_{12} (z_{1}, y_{1}) x_{2}, a_{2}, b_{2}}_{2} - {θ_{12} (x_{1}, y_{1}) z_{2}, a_{2}, b_{2}}_{2} - θ_{12} (b_{1}, a_{1}) {x_{2}, y_{2}, z_{2}}_{2} \\ + {z_{2}, θ_{13} (y_{1}, a_{1}) x_{2}, b_{2}}_{2} + {z_{2}, θ_{12} (a_{1}, x_{1}) y_{2}, b_{2}}_{2} + {z_{2}, θ_{12} (y_{1}, x_{1}) a_{2}, b_{2}}_{2} + θ_{13} (z_{1}, b_{1}) {y_{2}, x_{2}, a_{2}}_{2} \end{matrix}$ ，

由 $(J_{1}, {\cdot, \cdot, \cdot}_{1}), (J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系知(1.2)式成立，由(2.4)式成立知A₁为零，由(2.5)式成立知A₂为零，由(2.2)式成立知A₃为零，由(2.3)式成立知A₄为零，由(2.2)式成立知A₅为零。由于 $θ_{12}, θ_{13}$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的作用，故有 ${x_{2}, y_{2}, θ_{13} (z_{1}, b_{1}) a_{2}}_{2} = 0$ ， $θ_{12} (y_{1}, x_{1}) {z_{2}, a_{2}, b_{2}}_{2} = 0$ ，类似可知A₆为零。所以在 $J_{1} \oplus J_{2}$ 上(1.2)式成立。综上， $(J_{1} \oplus J_{2}, {\cdot, \cdot, \cdot}_{θ})$ 是一个约当三系。

定理2.1 $(J_{1}, {\cdot, \cdot, \cdot}_{1}), (J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系， $θ_{12}, θ_{13}$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的作用，则线性映射 $T : J_{2} \to J_{1}$ 是关于作用 $θ_{12}, θ_{13}$ 的权为 $λ$ 的相对Rota-Baxter算子当且仅当图 $G r (T) = {T u + u | u \in J_{2}}$ 是 $(J_{1} \oplus J_{2}, {\cdot, \cdot, \cdot}_{θ})$ 的子系。

证明：由于 $T : J_{2} \to J_{1}$ 是线性映射， $\forall u, v, w \in J_{2}$ ，由命题2.1有

${T u + u, T v + v, T w + w}_{θ} = {T u, T v, T w}_{1} + θ_{13} (T u, T w) v + θ_{12} (T w, T v) u + θ_{12} (T u, T v) w + λ {u, v, w}_{2}$ ，

这表明，图 $G r (T)$ 是 $(J_{1} \oplus J_{2}, {\cdot, \cdot, \cdot}_{θ})$ 的子系当且仅当T满足(2.6)式，所以结论成立。

4. 相对Rota-Baxter算子的应用

命题4.1 $(J_{1}, {\cdot, \cdot, \cdot}_{1}), (J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系，线性映射 $T : J_{2} \to J_{1}$ 是关于作用 $θ_{12}, θ_{13}$ 的权为 $λ$ 的相对Rota-Baxter算子，在 $J_{2}$ 上定义新运算 ${\cdot, \cdot, \cdot}_{T}$ ，其中

${u, v, w}_{T} = θ_{12} (T w, T v) u + θ_{13} (T u, T w) v + θ_{12} (T u, T v) w + λ {u, v, w}_{2}$ ，

$\forall u, v, w \in J_{2}$ ，则 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 也是约当三系，并且是从约当三系 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 到约当三系 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 的同态。

证明：显然，在 $J_{2}$ 上定义的新代数运算 ${\cdot, \cdot, \cdot}_{T}$ 对三个变量都是线性的，若要证明 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 是一个约当三系，只需在 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 上验证(1.1)~(1.2)式成立。 $\forall u_{1}, u_{2}, u_{3}, u_{4}, u_{5} \in J_{2}$ ，

$\begin{array}{l} {u_{1}, u_{2}, u_{3}}_{T} - {u_{3}, u_{2}, u_{1}}_{T} \\ = θ_{12} (T u_{3}, T u_{2}) u_{1} + θ_{13} (T u_{1}, T u_{3}) u_{2} + θ_{12} (T u_{1}, T u_{2}) u_{3} + λ {u_{1}, u_{2}, u_{3}}_{2} \\ - θ_{12} (T u_{1}, T u_{2}) u_{3} - θ_{13} (T u_{3}, T u_{1}) u_{2} - θ_{12} (T u_{3}, T u_{2}) u_{1} - λ {u_{3}, u_{2}, u_{1}}_{2} \end{array}$ ，

由于 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系且 $θ_{13}$ 是对称的，所以在 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 上(1.1)式成立。

$\begin{array}{l} {u_{1}, u_{2}, {u_{3}, u_{4}, u_{5}}_{T}}_{T} - {u_{3}, u_{4}, {u_{1}, u_{2}, u_{5}}_{T}}_{T} - {{u_{1}, u_{2}, u_{3}}_{T}, u_{4}, u_{5}}_{T} + {u_{3}, {u_{2}, u_{1}, u_{4}}_{T}, u_{5}}_{T} \\ = {u_{1}, u_{2}, θ_{12} (T u_{5}, T u_{4}) u_{3} + θ_{13} (T u_{3}, T u_{5}) u_{4} + θ_{12} (T u_{3}, T u_{4}) u_{5} + λ {u_{3}, u_{4}, u_{5}}_{2}}_{T} \\ - {u_{3}, u_{4}, θ_{12} (T u_{5}, T u_{2}) u_{1} + θ_{13} (T u_{1}, T u_{5}) u_{2} + θ_{12} (T u_{1}, T u_{2}) u_{5} + λ {u_{1}, u_{2}, u_{5}}_{2}}_{T} \\ - {θ_{12} (T u_{3}, T u_{2}) u_{1} + θ_{13} (T u_{1}, T u_{3}) u_{2} + θ_{12} (T u_{1}, T u_{2}) u_{3} + λ {u_{1}, u_{2}, u_{3}}_{2}, u_{4}, u_{5}}_{T} \\ + {u_{3}, θ_{12} (T u_{4}, T u_{1}) u_{2} + θ_{13} (T u_{2}, T u_{4}) u_{1} + θ_{12} (T u_{2}, T u_{1}) u_{4} + λ {u_{2}, u_{1}, u_{4}}_{2}, u_{5}}_{T} \end{array}$

$\begin{array}{l} = θ_{12} (T (θ_{12} (T u_{5}, T u_{4}) u_{3}), T u_{2}) u_{1} + θ_{13} (T u_{1}, T (θ_{12} (T u_{5}, T u_{4}) u_{3})) u_{2} + θ_{12} (T u_{1}, T u_{2}) θ_{12} (T u_{5}, T u_{4}) u_{3} \\ + λ {u_{1}, u_{2}, θ_{12} (T u_{5}, T u_{4}) u_{3}}_{2} + θ_{12} (T (θ_{13} (T u_{3}, T u_{5}) u_{4}), T u_{2}) u_{1} + θ_{13} (T u_{1}, T (θ_{13} (T u_{3}, T u_{5}) u_{4})) u_{2} \\ + θ_{12} (T u_{1}, T u_{2}) θ_{13} (T u_{3}, T u_{5}) u_{4} + λ {u_{1}, u_{2}, θ_{13} (T u_{3}, T u_{5}) u_{4}}_{2} + θ_{12} (T (θ_{12} (T u_{3}, T u_{4}) u_{5}), T u_{2}) u_{1} \\ + θ_{13} (T u_{1}, T (θ_{12} (T u_{3}, T u_{4}) u_{5})) u_{2} + θ_{12} (T u_{1}, T u_{2}) θ_{12} (T u_{3}, T u_{4}) u_{5} + λ {u_{1}, u_{2}, θ_{12} (T u_{3}, T u_{4}) u_{5}}_{2} \\ + θ_{12} (T (λ {u_{3}, u_{4}, u_{5}}_{2}), T u_{2}) u_{1} + θ_{13} (T u_{1}, T (λ {u_{3}, u_{4}, u_{5}}_{2})) u_{2} + λ θ_{12} (T u_{1}, T u_{2}) {u_{3}, u_{4}, u_{5}}_{2} \end{array}$

$\begin{array}{l} + λ {u_{1}, u_{2}, λ {u_{3}, u_{4}, u_{5}}_{2}}_{2} - θ_{12} (T (θ_{12} (T u_{5}, T u_{2}) u_{1}), T u_{4}) u_{3} - θ_{13} (T u_{3}, T (θ_{12} (T u_{5}, T u_{2}) u_{1})) u_{4} \\ - θ_{12} (T u_{3}, T u_{4}) θ_{12} (T u_{5}, T u_{2}) u_{1} - λ {u_{3}, u_{4}, θ_{12} (T u_{5}, T u_{2}) u_{1}}_{2} - θ_{12} (T (θ_{13} (T u_{1}, T u_{5}) u_{2}), T u_{4}) u_{3} \\ - θ_{13} (T u_{3}, T (θ_{13} (T u_{1}, T u_{5}) u_{2})) u_{4} - θ_{12} (T u_{3}, T u_{4}) θ_{13} (T u_{1}, T u_{5}) u_{2} - λ {u_{3}, u_{4}, θ_{13} (T u_{1}, T u_{5}) u_{2}}_{2} \\ - θ_{12} (T (θ_{12} (T u_{1}, T u_{2}) u_{5}), T u_{4}) u_{3} - θ_{13} (T u_{3}, T (θ_{12} (T u_{1}, T u_{2}) u_{5})) u_{4} - θ_{12} (T u_{3}, T u_{4}) θ_{12} (T u_{1}, T u_{2}) u_{5} \\ - λ {u_{3}, u_{4}, θ_{12} (T u_{1}, T u_{2}) u_{5}}_{2} - θ_{12} (T (λ {u_{1}, u_{2}, u_{5}}_{2}), T u_{4}) u_{3} - θ_{13} (T u_{3}, T (λ {u_{1}, u_{2}, u_{5}}_{2})) u_{4} \end{array}$

$\begin{array}{l} - λ θ_{12} (T u_{3}, T u_{4}) {u_{1}, u_{2}, u_{5}}_{2} - λ {u_{3}, u_{4}, λ {u_{1}, u_{2}, u_{5}}_{2}}_{2} - θ_{12} (T u_{5}, T u_{4}) θ_{12} (T u_{3}, T u_{2}) u_{1} \\ - θ_{13} (T (θ_{12} (T u_{3}, T u_{2}) u_{1}), T u_{5}) u_{4} - θ_{12} (T (θ_{12} (T u_{3}, T u_{2}) u_{1}), T u_{4}) u_{5} - λ {θ_{12} (T u_{3}, T u_{2}) u_{1}, u_{4}, u_{5}}_{2} \\ - θ_{12} (T u_{5}, T u_{4}) θ_{13} (T u_{1}, T u_{3}) u_{2} - θ_{13} (T (θ_{13} (T u_{1}, T u_{3}) u_{2}), T u_{5}) u_{4} - θ_{12} (T (θ_{13} (T u_{1}, T u_{3}) u_{2}), T u_{4}) u_{5} \\ - λ {θ_{13} (T u_{1}, T u_{3}) u_{2}, u_{4}, u_{5}}_{2} - θ_{12} (T u_{5}, T u_{4}) θ_{12} (T u_{1}, T u_{2}) u_{3} - θ_{13} (T (θ_{12} (T u_{1}, T u_{2}) u_{3}), T u_{5}) u_{4} \\ - θ_{12} (T (θ_{12} (T u_{1}, T u_{2}) u_{3}), T u_{4}) u_{5} - λ {θ_{12} (T u_{1}, T u_{2}) u_{3}, u_{4}, u_{5}}_{2} - λ θ_{12} (T u_{5}, T u_{4}) {u_{1}, u_{2}, u_{3}}_{2} \end{array}$

$\begin{array}{l} - θ_{13} (T (λ {u_{1}, u_{2}, u_{3}}_{2}), T u_{5}) u_{4} - θ_{12} (T (λ {u_{1}, u_{2}, u_{3}}_{2}), T u_{4}) u_{5} - λ {λ {u_{1}, u_{2}, u_{3}}_{2}, u_{4}, u_{5}}_{2} \\ + θ_{12} (T u_{5}, T (θ_{12} (T u_{4}, T u_{1}) u_{2})) u_{3} + θ_{13} (T u_{3}, T u_{5}) θ_{12} (T u_{4}, T u_{1}) u_{2} + θ_{12} (T u_{3}, T (θ_{12} (T u_{4}, T u_{1}) u_{2})) u_{5} \\ + λ {u_{3}, θ_{12} (T u_{4}, T u_{1}) u_{2}, u_{5}}_{2} + θ_{12} (T u_{5}, T (θ_{13} (T u_{2}, T u_{4}) u_{1})) u_{3} + θ_{13} (T u_{3}, T u_{5}) θ_{13} (T u_{2}, T u_{4}) u_{1} \\ + θ_{12} (T u_{3}, T (θ_{13} (T u_{2}, T u_{4}) u_{1})) u_{5} + λ {u_{3}, θ_{13} (T u_{2}, T u_{4}) u_{1}, u_{5}}_{2} + θ_{12} (T u_{5}, T (θ_{12} (T u_{2}, T u_{1}) u_{4})) u_{3} \\ + θ_{13} (T u_{3}, T u_{5}) θ_{12} (T u_{2}, T u_{1}) u_{4} + θ_{12} (T u_{3}, T (θ_{12} (T u_{2}, T u_{1}) u_{4})) u_{5} + λ {u_{3}, θ_{12} (T u_{2}, T u_{1}) u_{4}, u_{5}}_{2} \end{array}$

$\begin{array}{l} + θ_{12} (T u_{5}, T (λ {u_{2}, u_{1}, u_{4}}_{2})) u_{3} + λ θ_{13} (T u_{3}, T u_{5}) {u_{2}, u_{1}, u_{4}}_{2} + θ_{12} (T u_{3}, T (λ {u_{2}, u_{1}, u_{4}}_{2})) u_{5} \\ + λ {u_{3}, λ {u_{2}, u_{1}, u_{4}}_{2}, u_{5}}_{2} \\ = λ^{2} ({u_{1}, u_{2}, {u_{3}, u_{4}, u_{5}}_{2}}_{2} - {u_{3}, u_{4}, {u_{1}, u_{2}, u_{5}}_{2}}_{2} - {{u_{1}, u_{2}, u_{3}}_{2}, u_{4}, u_{5}}_{2} + {u_{3}, {u_{2}, u_{1}, u_{4}}_{2}, u_{5}}_{2}) \\ + B_{1} u_{1} + B_{2} u_{2} + B_{3} u_{3} + B_{4} u_{4} + B_{5} u_{5} + λ B_{6} \end{array}$

其中，

$\begin{matrix} B_{1} = θ_{12} (T (θ_{12} (T u_{5}, T u_{4}) u_{3}), T u_{2}) + θ_{12} (T (θ_{13} (T u_{3}, T u_{5}) u_{4}), T u_{2}) + θ_{12} (T (θ_{12} (T u_{3}, T u_{4}) u_{5}), T u_{2}) \\ + θ_{12} (T (λ {u_{3}, u_{4}, u_{5}}_{2}), T u_{2}) - θ_{12} (T u_{3}, T u_{4}) θ_{12} (T u_{5}, T u_{2}) - θ_{12} (T u_{5}, T u_{4}) θ_{12} (T u_{3}, T u_{2}) \\ + θ_{13} (T u_{3}, T u_{5}) θ_{13} (T u_{2}, T u_{4}) \end{matrix}$ ，

$\begin{matrix} B_{2} = θ_{13} (T u_{1}, T (θ_{12} (T u_{5}, T u_{4}) u_{3})) + θ_{13} (T u_{1}, T (θ_{13} (T u_{3}, T u_{5}) u_{4})) + θ_{13} (T u_{1}, T (θ_{12} (T u_{3}, T u_{4}) u_{5})) \\ + θ_{13} (T u_{1}, T (λ {u_{3}, u_{4}, u_{5}}_{2})) - θ_{12} (T u_{3}, T u_{4}) θ_{13} (T u_{1}, T u_{5}) - θ_{12} (T u_{5}, T u_{4}) θ_{13} (T u_{1}, T u_{3}) \\ + θ_{13} (T u_{3}, T u_{5}) θ_{12} (T u_{4}, T u_{1}) \end{matrix}$ ，

$\begin{matrix} B_{3} = θ_{12} (T u_{1}, T u_{2}) θ_{12} (T u_{5}, T u_{4}) - θ_{12} (T (θ_{12} (T u_{5}, T u_{2}) u_{1}), T u_{4}) - θ_{12} (T (θ_{13} (T u_{1}, T u_{5}) u_{2}), T u_{4}) \\ - θ_{12} (T (θ_{12} (T u_{1}, T u_{2}) u_{5}), T u_{4}) - θ_{12} (T (λ {u_{1}, u_{2}, u_{5}}_{2}), T u_{4}) - θ_{12} (T u_{5}, T u_{4}) θ_{12} (T u_{1}, T u_{2}) \\ + θ_{12} (T u_{5}, T (θ_{12} (T u_{4}, T u_{1}) u_{2})) + θ_{12} (T u_{5}, T (θ_{13} (T u_{2}, T u_{4}) u_{1})) + θ_{12} (T u_{5}, T (θ_{12} (T u_{2}, T u_{1}) u_{4})) \\ + θ_{12} (T u_{5}, T (λ {u_{2}, u_{1}, u_{4}}_{2})) \end{matrix}$ ，

$\begin{matrix} B_{4} = θ_{12} (T u_{1}, T u_{2}) θ_{13} (T u_{3}, T u_{5}) - θ_{13} (T u_{3}, T (θ_{12} (T u_{5}, T u_{2}) u_{1})) - θ_{13} (T u_{3}, T (θ_{13} (T u_{1}, T u_{5}) u_{2})) \\ - θ_{13} (T u_{3}, T (θ_{12} (T u_{1}, T u_{2}) u_{5})) - θ_{13} (T u_{3}, T (λ {u_{1}, u_{2}, u_{5}}_{2})) - θ_{13} (T (θ_{12} (T u_{3}, T u_{2}) u_{1}), T u_{5}) \\ - θ_{13} (T (θ_{13} (T u_{1}, T u_{3}) u_{2}), T u_{5}) - θ_{13} (T (θ_{12} (T u_{1}, T u_{2}) u_{3}), T u_{5}) - θ_{13} (T (λ {u_{1}, u_{2}, u_{3}}_{2}), T u_{5}) \\ + θ_{13} (T u_{3}, T u_{5}) θ_{12} (T u_{2}, T u_{1}) \end{matrix}$ ，

$\begin{matrix} B_{5} = θ_{12} (T u_{1}, T u_{2}) θ_{12} (T u_{3}, T u_{4}) - θ_{12} (T u_{3}, T u_{4}) θ_{12} (T u_{1}, T u_{2}) - θ_{12} (T (θ_{12} (T u_{3}, T u_{2}) u_{1}), T u_{4}) \\ - θ_{12} (T (θ_{13} (T u_{1}, T u_{3}) u_{2}), T u_{4}) - θ_{12} (T (θ_{12} (T u_{1}, T u_{2}) u_{3}), T u_{4}) - θ_{12} (T (λ {u_{1}, u_{2}, u_{3}}_{2}), T u_{4}) \\ + θ_{12} (T u_{3}, T (θ_{12} (T u_{4}, T u_{1}) u_{2})) + θ_{12} (T u_{3}, T (θ_{13} (T u_{2}, T u_{4}) u_{1})) + θ_{12} (T u_{3}, T (θ_{12} (T u_{2}, T u_{1}) u_{4})) \\ + θ_{12} (T u_{3}, T (λ {u_{2}, u_{1}, u_{4}}_{2})) \end{matrix}$ ，

$\begin{matrix} B_{6} = {u_{1}, u_{2}, θ_{12} (T u_{5}, T u_{4}) u_{3}}_{2} + {u_{1}, u_{2}, θ_{13} (T u_{3}, T u_{5}) u_{4}}_{2} + {u_{1}, u_{2}, θ_{12} (T u_{3}, T u_{4}) u_{5}}_{2} \\ + θ_{12} (T u_{1}, T u_{2}) {u_{3}, u_{4}, u_{5}}_{2} - {u_{3}, u_{4}, θ_{12} (T u_{5}, T u_{2}) u_{1}}_{2} - {u_{3}, u_{4}, θ_{13} (T u_{1}, T u_{5}) u_{2}}_{2} \\ - {u_{3}, u_{4}, θ_{12} (T u_{1}, T u_{2}) u_{5}}_{2} - θ_{12} (T u_{3}, T u_{4}) {u_{1}, u_{2}, u_{5}}_{2} - {θ_{12} (T u_{3}, T u_{2}) u_{1}, u_{4}, u_{5}}_{2} \\ - {θ_{13} (T u_{1}, T u_{3}) u_{2}, u_{4}, u_{5}}_{2} - {θ_{12} (T u_{1}, T u_{2}) u_{3}, u_{4}, u_{5}}_{2} - θ_{12} (T u_{5}, T u_{4}) {u_{1}, u_{2}, u_{3}}_{2} \\ + {u_{3}, θ_{12} (T u_{4}, T u_{1}) u_{2}, u_{5}}_{2} + {u_{3}, θ_{13} (T u_{2}, T u_{4}) u_{1}, u_{5}}_{2} + {u_{3}, θ_{12} (T u_{2}, T u_{1}) u_{4}, u_{5}}_{2} \\ + θ_{13} (T u_{3}, T u_{5}) {u_{2}, u_{1}, u_{4}}_{2} \end{matrix}$ ，

由 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系知(1.2)式成立，由(2.4)式成立知B₁为零，由(2.5)式成立知B₂为零，由(2.2)式成立知B₃为零，由(2.3)式成立知B₄为零，由(2.2)式成立知B₅为零，由于 $θ_{12}, θ_{13}$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的作用，故有 ${u_{1}, u_{2}, θ_{12} (T u_{5}, T u_{4}) u_{3}}_{2} = 0$ ， $θ_{12} (T u_{1}, T u_{2}) {u_{3}, u_{4}, u_{5}}_{2} = 0$ ，类似可知B₆为零。故在 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 上(1.2)式成立。综上， $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 也是约当三系。

下证T是从 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 到 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 的同态。由于线性映射 $T : J_{2} \to J_{1}$ 是关于作用 $θ_{12}, θ_{13}$ 的权为 $λ$ 的相对Rota-Baxter算子，所以，

$T ({u, v, w}_{T}) = T (θ_{12} (T w, T v) u + θ_{13} (T u, T w) v + θ_{12} (T u, T v) w + λ {u, v, w}_{2}) = {T u, T v, T w}_{1}$ ，

$\forall u, v, w \in J_{2}$ ，因此，T是从 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 到 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 的代数同态。

命题3.2 $(J_{1}, {\cdot, \cdot, \cdot}_{1}), (J_{2}, {\cdot, \cdot, \cdot}_{2})$ 是约当三系，线性映射 $T : J_{2} \to J_{1}$ 是关于作用 $θ_{12}, θ_{13}$ 的权为 $λ$ 的相对Rota-Baxter算子，定义双线性映射 $L_{T}, M_{T} : J_{2} \times J_{2} \to E n d (J_{1})$ ，其中

$L_{T} (u, v) x = {T u, T v, x}_{1} - T (θ_{13} (T u, x) v + θ_{12} (x, T v) u)$ ，

$M_{T} (u, v) x = {T u, x, T v}_{1} - T (θ_{12} (T v, x) u + θ_{12} (T u, x) v)$ ，

$x \in J_{1}, u, v \in J_{2}$ ，则 $(L_{T}, M_{T}, J_{1})$ 是 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 的表示。

证：显然， $L_{T}, M_{T}$ 是线性映射， $\forall u_{1}, u_{2}, u_{3}, u_{4} \in J_{2}, x \in J_{1}$ ，计算(2.1)式左边可得

$\begin{array}{l} (M_{T} (u_{1}, u_{2}) - M_{T} (u_{2}, u_{1})) x \\ = {T u_{1}, x, T u_{2}}_{1} - T (θ_{12} (T u_{2}, x) u_{1} + θ_{12} (T u_{1}, x) u_{2}) - {T u_{2}, x, T u_{1}}_{1} + T (θ_{12} (T u_{1}, x) u_{2} + θ_{12} (T u_{2}, x) u_{1}) \end{array}$ ，

由于 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 是约当三系，故(2.1)式成立。

计算(2.2)式左边可得

$\begin{array}{l} (L_{T} (u_{1}, u_{2}) L_{T} (u_{3}, u_{4}) - L_{T} (u_{3}, u_{4}) L_{T} (u_{1}, u_{2}) - L_{T} ({u_{1}, u_{2}, u_{3}}_{T}, u_{4}) + L_{T} (u_{3}, {u_{2}, u_{1}, u_{4}}_{T})) x \\ = L_{T} (u_{1}, u_{2}) {T u_{3}, T u_{4}, x}_{1} - L_{T} (u_{1}, u_{2}) T θ_{12} (x, T u_{4}) u_{3} - L_{T} (u_{1}, u_{2}) T θ_{13} (T u_{3}, x) u_{4} \\ - L_{T} (u_{3}, u_{4}) {T u_{1}, T u_{2}, x}_{1} + L_{T} (u_{3}, u_{4}) T θ_{12} (x, T u_{2}) u_{1} + L_{T} (u_{3}, u_{4}) T θ_{13} (T u_{1}, x) u_{2} \\ - {{T u_{1}, T u_{2}, T u_{3}}_{1}, T u_{4}, x}_{1} + T θ_{12} (x, T u_{4}) {u_{1}, u_{2}, u_{3}}_{T} + T θ_{13} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) u_{4} \\ + {T u_{3}, {T u_{2}, T u_{1}, T u_{4}}_{1}, x}_{1} - T θ_{12} (x, {T u_{2}, T u_{1}, T u_{4}}_{1}) u_{3} - T θ_{13} (T u_{3}, x) {u_{2}, u_{1}, u_{4}}_{T} \end{array}$

$\begin{array}{l} = {T u_{1}, T u_{2}, {T u_{3}, T u_{4}, x}_{1}}_{1} - T θ_{12} ({T u_{3}, T u_{4}, x}_{1}, T u_{2}) u_{1} - T θ_{13} (T u_{1}, {T u_{3}, T u_{4}, x}_{1}) u_{2} \\ - {T u_{1}, T u_{2}, T θ_{12} (x, T u_{4}) u_{3}}_{1} + T θ_{12} (T θ_{12} (x, T u_{4}) u_{3}, T u_{2}) u_{1} + T θ_{13} (T u_{1}, T θ_{12} (x, T u_{4}) u_{3}) u_{2} \\ - {T u_{1}, T u_{2}, T θ_{13} (T u_{3}, x) u_{4}}_{1} + T θ_{12} (T θ_{13} (T u_{3}, x) u_{4}, T u_{2}) u_{1} + T θ_{13} (T u_{1}, T θ_{13} (T u_{3}, x) u_{4}) u_{2} \\ - {T u_{3}, T u_{4}, {T u_{1}, T u_{2}, x}_{1}}_{1} + T θ_{12} ({T u_{1}, T u_{2}, x}_{1}, T u_{4}) u_{3} + T θ_{13} (T u_{3}, {T u_{1}, T u_{2}, x}_{1}) u_{4} \\ + {T u_{3}, T u_{4}, T θ_{12} (x, T u_{2}) u_{1}}_{1} - T θ_{12} (T θ_{12} (x, T u_{2}) u_{1}, T u_{4}) u_{3} - T θ_{13} (T u_{3}, T θ_{12} (x, T u_{2}) u_{1}) u_{4} \end{array}$

$\begin{array}{l} + {T u_{3}, T u_{4}, T θ_{13} (T u_{1}, x) u_{2}}_{1} - T θ_{12} (T θ_{13} (T u_{1}, x) u_{2}, T u_{4}) u_{3} - T θ_{13} (T u_{3}, T θ_{13} (T u_{1}, x) u_{2}) u_{4} \\ - {{T u_{1}, T u_{2}, T u_{3}}_{1}, T u_{4}, x}_{1} + T θ_{13} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) u_{4} + T θ_{12} (x, T u_{4}) θ_{12} (T u_{3}, T u_{2}) u_{1} \\ + T θ_{12} (x, T u_{4}) θ_{12} (T u_{1}, T u_{2}) u_{3} + T θ_{12} (x, T u_{4}) θ_{13} (T u_{1}, T u_{3}) u_{2} + λ T θ_{12} (x, T u_{4}) {u_{1}, u_{2}, u_{3}}_{2} \\ + {T u_{3}, {T u_{2}, T u_{1}, T u_{4}}_{1}, x}_{1} - T θ_{12} (x, {T u_{2}, T u_{1}, T u_{4}}_{1}) u_{3} - T θ_{13} (T u_{3}, x) θ_{12} (T u_{4}, T u_{1}) u_{2} \\ - T θ_{13} (T u_{3}, x) θ_{12} (T u_{2}, T u_{1}) u_{4} - T θ_{13} (T u_{3}, x) θ_{13} (T u_{2}, T u_{4}) u_{1} - λ T θ_{13} (T u_{3}, x) {u_{2}, u_{1}, u_{4}}_{2} \end{array}$

$\begin{array}{l} = ({T u_{1}, T u_{2}, {T u_{3}, T u_{4}, x}_{1}}_{1} - {T u_{3}, T u_{4}, {T u_{1}, T u_{2}, x}_{1}}_{1} - {{T u_{1}, T u_{2}, T u_{3}}_{1}, T u_{4}, x}_{1} \\ + {T u_{3}, {T u_{2}, T u_{1}, T u_{4}}_{1}, x}_{1}) - T (C_{11} u_{1} + C_{12} u_{2} + C_{13} u_{3} + C_{14} u_{4} + λ C_{15}) \end{array}$

其中，

$C_{11} = θ_{12} ({T u_{3}, T u_{4}, x}_{1}, T u_{2}) - θ_{12} (T u_{3}, T u_{4}) θ_{12} (x, T u_{2}) - θ_{12} (x, T u_{4}) θ_{12} (T u_{3}, T u_{2}) + θ_{13} (T u_{3}, x) θ_{13} (T u_{2}, T u_{4})$ ，

$C_{12} = θ_{13} (T u_{1}, {T u_{3}, T u_{4}, x}_{1}) - θ_{12} (T u_{3}, T u_{4}) θ_{13} (T u_{1}, x) - θ_{12} (x, T u_{4}) θ_{13} (T u_{1}, T u_{3}) + θ_{13} (T u_{3}, x) θ_{12} (T u_{4}, T u_{1})$ ，

$C_{13} = θ_{12} (T u_{1}, T u_{2}) θ_{12} (x, T u_{4}) - θ_{12} ({T u_{1}, T u_{2}, x}_{1}, T u_{4}) - θ_{12} (x, T u_{4}) θ_{12} (T u_{1}, T u_{2}) + θ_{12} (x, {T u_{2}, T u_{1}, T u_{4}}_{1})$ ，

$C_{14} = θ_{12} (T u_{1}, T u_{2}) θ_{13} (T u_{3}, x) - θ_{13} (T u_{3}, {T u_{1}, T u_{2}, x}_{1}) - θ_{13} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) + θ_{13} (T u_{3}, x) θ_{12} (T u_{2}, T u_{1})$ ，

$\begin{matrix} C_{15} = {u_{1}, u_{2}, θ_{12} (x, T u_{4}) u_{3}}_{2} + {u_{1}, u_{2}, θ_{13} (T u_{3}, x)}_{2} - {u_{3}, u_{4}, θ_{12} (x, T u_{2}) u_{1}}_{2} - {u_{3}, u_{4}, θ_{13} (T u_{1}, x)}_{2} \\ - θ_{12} (x, T u_{4}) {u_{1}, u_{2}, u_{3}}_{2} + θ_{13} (T u_{3}, x) {u_{2}, u_{1}, u_{4}}_{2} \end{matrix}$ ，

由于 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 是约当三系，故(1.2)式成立，由(2.4)式成立知C₁₁为零，由(2.5)式成立知C₁₂为零，由(2.2)式成立知C₁₃为零，由(2.3)式成立知C₁₄为零，由于 $θ_{12}, θ_{13}$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的作用，故有 ${u_{1}, u_{2}, θ_{12} (x, T u_{4}) u_{3}}_{2} = 0$ ， $θ_{12} (x, T u_{4}) {u_{1}, u_{2}, u_{3}}_{2} = 0$ ，类似可知C₁₅为零，故(2.2)式成立。

计算(2.3)式左边可得

$\begin{array}{l} (L_{T} (u_{1}, u_{2}) M_{T} (u_{3}, u_{4}) + M_{T} (u_{3}, u_{4}) L_{T} (u_{2}, u_{1}) - M_{T} (u_{3}, {u_{1}, u_{2}, u_{4}}_{T}) - M_{T} ({u_{1}, u_{2}, u_{3}}_{T}, u_{4})) x \\ = L_{T} (u_{1}, u_{2}) {T u_{3}, x, T u_{4}}_{1} - L_{T} (u_{1}, u_{2}) T θ_{12} (T u_{4}, x) u_{3} - L_{T} (u_{1}, u_{2}) T θ_{12} (T u_{3}, x) u_{4} \\ + M_{T} (u_{3}, u_{4}) {T u_{2}, T u_{1}, x}_{1} - M_{T} (u_{3}, u_{4}) T θ_{13} (T u_{2}, x) u_{1} - M_{T} (u_{3}, u_{4}) T θ_{12} (x, T u_{1}) u_{2} \\ - {T u_{3}, x, {T u_{1}, T u_{2}, T u_{4}}_{1}}_{1} + T θ_{12} (T u_{3}, x) {u_{1}, u_{2}, u_{4}}_{T} + T θ_{12} ({T u_{1}, T u_{2}, T u_{4}}_{1}, x) u_{3} \\ - {{T u_{1}, T u_{2}, T u_{3}}_{1}, x, T u_{4}}_{1} + T θ_{12} (T u_{4}, x) {u_{1}, u_{2}, u_{3}}_{T} + T θ_{12} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) u_{4} \end{array}$

$\begin{array}{l} = {T u_{1}, T u_{2}, {T u_{3}, x, T u_{4}}_{1}}_{1} - T θ_{13} (T u_{1}, {T u_{3}, x, T u_{4}}_{1}) u_{2} - T θ_{12} ({T u_{3}, x, T u_{4}}_{1}, T u_{2}) u_{1} \\ - {T u_{1}, T u_{2}, T θ_{12} (T u_{4}, x) u_{3}}_{1} + T θ_{13} (T u_{1}, T θ_{12} (T u_{4}, x) u_{3}) u_{2} + T θ_{12} (T θ_{12} (T u_{4}, x) u_{3}, T u_{2}) u_{1} \\ - {T u_{1}, T u_{2}, T θ_{12} (T u_{3}, x) u_{4}}_{1} + T θ_{13} (T u_{1}, T θ_{12} (T u_{3}, x) u_{4}) u_{2} + T θ_{12} (T θ_{12} (T u_{3}, x) u_{4}, T u_{2}) u_{1} \\ + {T u_{3}, {T u_{2}, T u_{1}, x}_{1}, T u_{4}}_{1} - T θ_{12} (T u_{4}, {T u_{2}, T u_{1}, x}_{1}) u_{3} - T θ_{12} (T u_{3}, {T u_{2}, T u_{1}, x}_{1}) u_{4} \\ - {T u_{3}, T θ_{13} (T u_{2}, x) u_{1}, T u_{4}}_{1} + T θ_{12} (T u_{4}, T θ_{13} (T u_{2}, x) u_{1}) u_{3} + T θ_{12} (T u_{3}, T θ_{13} (T u_{2}, x) u_{1}) u_{4} \end{array}$

$\begin{array}{l} - {T u_{3}, T θ_{12} (x, T u_{1}) u_{2}, T u_{4}}_{1} + T θ_{12} (T u_{4}, T θ_{12} (x, T u_{1}) u_{2}) u_{3} + T θ_{12} (T u_{3}, T θ_{12} (x, T u_{1}) u_{2}) u_{4} \\ - {T u_{3}, x, {T u_{1}, T u_{2}, T u_{4}}_{1}}_{1} + T θ_{12} ({T u_{1}, T u_{2}, T u_{4}}_{1}, x) u_{3} + T θ_{12} (T u_{3}, x) θ_{12} (T u_{4}, T u_{2}) u_{1} \\ + T θ_{12} (T u_{3}, x) θ_{12} (T u_{1}, T u_{2}) u_{4} + T θ_{12} (T u_{3}, x) θ_{13} (T u_{1}, T u_{4}) u_{2} + λ T θ_{12} (T u_{3}, x) {u_{1}, u_{2}, u_{4}}_{2} \\ - {{T u_{1}, T u_{2}, T u_{3}}_{1}, x, T u_{4}}_{1} + T θ_{12} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) u_{4} + T θ_{12} (T u_{4}, x) θ_{12} (T u_{3}, T u_{2}) u_{1} \\ + T θ_{12} (T u_{4}, x) θ_{12} (T u_{1}, T u_{2}) u_{3} + T θ_{12} (T u_{4}, x) θ_{13} (T u_{1}, T u_{3}) u_{2} + λ T \end{array}$

$\begin{array}{l} = ({T u_{1}, T u_{2}, {T u_{3}, x, T u_{4}}_{1}}_{1} - {T u_{3}, x, {T u_{1}, T u_{2}, T u_{4}}_{1}}_{1} - {{T u_{1}, T u_{2}, T u_{3}}_{1}, x, T u_{4}}_{1} \\ + {T u_{3}, {T u_{2}, T u_{1}, x}_{1}, T u_{4}}_{1}) - T (C_{21} u_{1} + C_{22} u_{2} + C_{23} u_{3} + C_{24} u_{4} + λ C_{25}) \end{array}$

其中，

$C_{21} = θ_{12} ({T u_{3}, x, T u_{4}}_{1}, T u_{2}) + θ_{13} (T u_{3}, T u_{4}) θ_{13} (T u_{2}, x) - θ_{12} (T u_{3}, x) θ_{12} (T u_{4}, T u_{2}) - θ_{12} (T u_{4}, x) θ_{12} (T u_{3}, T u_{2})$ ，

$C_{22} = θ_{13} (T u_{1}, {T u_{3}, x, T u_{4}}_{1}) + θ_{13} (T u_{3}, T u_{4}) θ_{12} (x, T u_{1}) - θ_{12} (T u_{3}, x) θ_{13} (T u_{1}, T u_{4}) - θ_{12} (T u_{4}, x) θ_{13} (T u_{1}, T u_{3})$ ，

$C_{23} = θ_{12} (T u_{1}, T u_{2}) θ_{12} (T u_{4}, x) + θ_{12} (T u_{4}, {T u_{2}, T u_{1}, x}_{1}) - θ_{12} ({T u_{1}, T u_{2}, T u_{4}}_{1}, x) - θ_{12} (T u_{4}, x) θ_{12} (T u_{1}, T u_{2})$ ，

$C_{24} = θ_{12} (T u_{1}, T u_{2}) θ_{12} (T u_{3}, x) + θ_{12} (T u_{3}, {T u_{2}, T u_{1}, x}_{1}) - θ_{12} (T u_{3}, x) θ_{12} (T u_{1}, T u_{2}) - θ_{12} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x)$ ，

$\begin{matrix} C_{25} = {u_{1}, u_{2}, θ_{12} (T u_{4}, x) u_{3}}_{2} + {u_{1}, u_{2}, θ_{12} (T u_{3}, x) u_{4}}_{1} - θ_{12} (T u_{4}, x) {u_{1}, u_{2}, u_{3}}_{2} \\ + {u_{3}, θ_{13} (T u_{2}, x) u_{1}, u_{4}}_{1} + {u_{3}, θ_{12} (x, T u_{1}) u_{2}, u_{4}}_{1} - θ_{12} (T u_{3}, x) {u_{1}, u_{2}, u_{4}}_{2} \end{matrix}$ ，

由于 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 是约当三系，故(1.2)式成立，由(2.4)式成立知C₂₁为零，由(2.5)式成立知C₂₂为零，由(2.2)式成立知C₂₃为零，由(2.2)式成立知C₂₄为零，由于 $θ_{12}, θ_{13}$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的作用，故有 ${u_{3}, θ_{13} (x, T u_{2}) u_{1}, u_{4}}_{2} = 0$ ， $θ_{12} (x, T u_{4}) {u_{1}, u_{2}, u_{3}}_{2} = 0$ ，类似可知C₂₅为零，故(2.3)式成立。

计算(2.4)式左边可得

$\begin{array}{l} (L_{T} ({u_{1}, u_{2}, u_{3}}_{T}, u_{4}) - L_{T} (u_{1}, u_{2}) L_{T} (u_{3}, u_{4}) - L_{T} (u_{3}, u_{2}) L_{T} (u_{1}, u_{4}) + M_{T} (u_{1}, u_{3}) M_{T} (u_{2}, u_{4})) x \\ = {{T u_{1}, T u_{2}, T u_{3}}_{1}, T u_{4}, x}_{1} - T θ_{13} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) u_{4} - T θ_{12} (x, T u_{4}) {u_{1}, u_{2}, u_{3}}_{T} \\ - L_{T} (u_{1}, u_{2}) {T u_{3}, T u_{4}, x}_{1} + L_{T} (u_{1}, u_{2}) T θ_{13} (T u_{3}, x) u_{4} + L_{T} (u_{1}, u_{2}) T θ_{12} (x, T u_{4}) u_{3} \\ - L_{T} (u_{3}, u_{2}) {T u_{1}, T u_{4}, x}_{1} + L_{T} (u_{3}, u_{2}) T θ_{13} (T u_{1}, x) u_{4} + L_{T} (u_{3}, u_{2}) T θ_{12} (x, T u_{4}) u_{1} \\ + M_{T} (u_{1}, u_{3}) {T u_{2}, x, T u_{4}}_{1} - M_{T} (u_{1}, u_{3}) T θ_{12} (T u_{4}, x) u_{2} - M_{T} (u_{1}, u_{3}) T θ_{12} (T u_{2}, x) u_{4} \end{array}$

$\begin{array}{l} = {{T u_{1}, T u_{2}, T u_{3}}_{1}, T u_{4}, x}_{1} - T θ_{13} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) u_{4} - T θ_{12} (x, T u_{4}) θ_{12} (T u_{3}, T u_{2}) u_{1} \\ - T θ_{12} (x, T u_{4}) θ_{12} (T u_{1}, T u_{2}) u_{3} - T θ_{12} (x, T u_{4}) θ_{13} (T u_{1}, T u_{3}) u_{2} - λ T θ_{12} (x, T u_{4}) {u_{1}, u_{2}, u_{3}}_{2} \\ - {T u_{1}, T u_{2}, {T u_{3}, T u_{4}, x}_{1}}_{1} + T θ_{13} (T u_{1}, {T u_{3}, T u_{4}, x}_{1}) u_{2} + T θ_{12} ({T u_{3}, T u_{4}, x}_{1}, T u_{2}) u_{1} \\ + {T u_{1}, T u_{2}, T θ_{13} (T u_{3}, x) u_{4}}_{1} - T θ_{13} (T u_{1}, T θ_{13} (T u_{3}, x) u_{4}) u_{2} - T θ_{12} (T θ_{13} (T u_{3}, x) u_{4}, T u_{2}) u_{1} \\ + {T u_{1}, T u_{2}, T θ_{12} (x, T u_{4}) u_{3}}_{1} - T θ_{13} (T u_{1}, T θ_{12} (x, T u_{4}) u_{3}) u_{2} - T θ_{12} (T θ_{12} (x, T u_{4}) u_{3}, T u_{2}) u_{1} \end{array}$

$\begin{array}{l} - {T u_{3}, T u_{2}, {T u_{1}, T u_{4}, x}_{1}}_{1} + T θ_{13} (T u_{3}, {T u_{1}, T u_{4}, x}_{1}) u_{2} + T θ_{12} ({T u_{1}, T u_{4}, x}_{1}, T u_{2}) u_{3} \\ + {T u_{3}, T u_{2}, T θ_{13} (T u_{1}, x) u_{4}}_{1} - T θ_{13} (T u_{3}, T θ_{13} (T u_{1}, x) u_{4}) u_{2} - T θ_{12} (T θ_{13} (T u_{1}, x) u_{4}, T u_{2}) u_{3} \\ + {T u_{3}, T u_{2}, T θ_{12} (x, T u_{4}) u_{1}}_{1} - T θ_{13} (T u_{3}, T θ_{12} (x, T u_{4}) u_{1}) u_{2} - T θ_{12} (T θ_{12} (x, T u_{4}) u_{1}, T u_{2}) u_{3} \\ + {T u_{1}, {T u_{2}, x, T u_{4}}_{1}, T u_{3}}_{1} - T θ_{12} (T u_{3}, {T u_{2}, x, T u_{4}}_{1}) u_{1} - T θ_{12} (T u_{1}, {T u_{2}, x, T u_{4}}_{1}) u_{3} \end{array}$

$\begin{array}{l} - {T u_{1}, T θ_{12} (T u_{4}, x) u_{2}, T u_{3}}_{1} + T θ_{12} (T u_{3}, T θ_{12} (T u_{4}, x) u_{2}) u_{1} + T θ_{12} (T u_{1}, T θ_{12} (T u_{4}, x) u_{2}) u_{3} \\ - {T u_{1}, T θ_{12} (T u_{2}, x) u_{4}, T u_{3}}_{1} + T θ_{12} (T u_{3}, T θ_{12} (T u_{2}, x) u_{4}) u_{1} + T θ_{12} (T u_{1}, T θ_{12} (T u_{2}, x) u_{4}) u_{3} \\ = {{T u_{1}, T u_{2}, T u_{3}}_{1}, T u_{4}, x}_{1} - {T u_{1}, T u_{2}, {T u_{3}, T u_{4}, x}_{1}}_{1} - {T u_{3}, T u_{2}, {T u_{1}, T u_{4}, x}_{1}}_{1} \\ + {T u_{1}, {T u_{2}, x, T u_{4}}_{1}, T u_{3}}_{1} - T (C_{31} u_{1} + C_{32} u_{2} + C_{33} u_{3} + C_{34} u_{4} + λ C_{35}) \end{array}$

其中，

$C_{31} = θ_{12} (x, T u_{4}) θ_{12} (T u_{3}, T u_{2}) - θ_{12} ({T u_{3}, T u_{4}, x}_{1}, T u_{2}) - θ_{12} (T u_{3}, T u_{2}) θ_{12} (x, T u_{4}) + θ_{12} (T u_{3}, {T u_{2}, x, T u_{4}}_{1})$ ，

$C_{32} = θ_{12} (x, T u_{4}) θ_{13} (T u_{1}, T u_{3}) - θ_{13} (T u_{1}, {T u_{3}, T u_{4}, x}_{1}) - θ_{13} (T u_{3}, {T u_{1}, T u_{4}, x}_{1}) + θ_{13} (T u_{1}, T u_{3}) θ_{12} (T u_{4}, x)$ ，

$C_{33} = θ_{12} (x, T u_{4}) θ_{12} (T u_{1}, T u_{2}) - θ_{12} (T u_{1}, T u_{2}) θ_{12} (x, T u_{4}) - θ_{12} ({T u_{1}, T u_{4}, x}_{1}, T u_{2}) + θ_{12} (T u_{1}, {T u_{2}, x, T u_{4}}_{1})$ ，

$C_{34} = θ_{13} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) - θ_{12} (T u_{1}, T u_{2}) θ_{13} (T u_{3}, x) - θ_{12} (T u_{3}, T u_{2}) θ_{13} (T u_{1}, x) + θ_{13} (T u_{1}, T u_{3}) θ_{12} (T u_{2}, x)$ ，

$\begin{matrix} C_{35} = θ_{12} (x, T u_{4}) {u_{1}, u_{2}, u_{3}}_{2} - {u_{1}, u_{2}, θ_{13} (T u_{3}, x) u_{4}}_{2} - {u_{1}, u_{2}, θ_{12} (x, T u_{4}) u_{3}}_{2} - {u_{3}, u_{2}, θ_{13} (T u_{1}, x) u_{4}}_{2} \\ - {u_{3}, u_{2}, θ_{12} (x, T u_{4}) u_{1}}_{2} + {u_{1}, θ_{12} (T u_{4}, x) u_{2}, u_{3}}_{2} + {u_{1}, θ_{12} (T u_{2}, x) u_{4}, u_{3}}_{2} \end{matrix}$ ，

由于 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 是约当三系，故(1.2)式成立，由(2.2)式成立知C₃₁为零，由(2.3)式成立知C₃₂为零，由(2.2)式成立知C₃₃为零，由(2.5)式成立知C₃₄为零，由于 $θ_{12}, θ_{13}$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的作用，故有 ${u_{1}, u_{2}, θ_{13} (T u_{3}, x) u_{4}}_{2} = 0$ ， $θ_{12} (x, T u_{4}) {u_{1}, u_{2}, u_{3}}_{2} = 0$ ，类似可知C₃₅为零，故(2.4)式成立。

计算(2.5)式左边可得

$\begin{array}{l} (M_{T} ({u_{1}, u_{2}, u_{3}}_{T}, u_{4}) - L_{T} (u_{1}, u_{2}) M_{T} (u_{3}, u_{4}) - L_{T} (u_{3}, u_{2}) M_{T} (u_{1}, u_{4}) + M_{T} (u_{1}, u_{3}) L_{T} (u_{2}, u_{4})) x \\ = {{T u_{1}, T u_{2}, T u_{3}}_{1}, x, T u_{4}}_{1} - T θ_{12} (T u_{4}, x) {u_{1}, u_{2}, u_{3}}_{T} - T θ_{12} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) u_{4} \\ - L_{T} (u_{1}, u_{2}) {T u_{3}, x, T u_{4}}_{1} + L_{T} (u_{1}, u_{2}) T θ_{12} (T u_{4}, x) u_{3} + L_{T} (u_{1}, u_{2}) T θ_{12} (T u_{3}, x) u_{4} \\ - L_{T} (u_{3}, u_{2}) {T u_{1}, x, T u_{4}}_{1} + L_{T} (u_{3}, u_{2}) T θ_{12} (T u_{4}, x) u_{1} + L_{T} (u_{3}, u_{2}) T θ_{12} (T u_{1}, x) u_{4} \\ + M_{T} (u_{1}, u_{3}) {T u_{2}, T u_{4}, x}_{1} - M_{T} (u_{1}, u_{3}) T θ_{13} (T u_{2}, x) u_{4} - M_{T} (u_{1}, u_{3}) T θ_{12} (x, T u_{4}) u_{2} \end{array}$

$\begin{array}{l} = {{T u_{1}, T u_{2}, T u_{3}}_{1}, x, T u_{4}}_{1} - T θ_{12} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) u_{4} - T θ_{12} (T u_{4}, x) θ_{12} (T u_{3}, T u_{2}) u_{1} \\ - T θ_{12} (T u_{4}, x) θ_{12} (T u_{1}, T u_{2}) u_{3} - T θ_{12} (T u_{4}, x) θ_{13} (T u_{1}, T u_{3}) u_{2} - λ T θ_{12} (T u_{4}, x) {u_{1}, u_{2}, u_{3}}_{2} \\ - {T u_{1}, T u_{2}, {T u_{3}, x, T u_{4}}_{1}}_{1} + T θ_{13} (T u_{1}, {T u_{3}, x, T u_{4}}_{1}) u_{2} + T θ_{12} ({T u_{3}, x, T u_{4}}_{1}, T u_{2}) u_{1} \\ + {T u_{1}, T u_{2}, T θ_{12} (T u_{4}, x) u_{3}}_{1} - T θ_{13} (T u_{1}, T θ_{12} (T u_{4}, x) u_{3}) u_{2} - T θ_{12} (T θ_{12} (T u_{4}, x) u_{3}, T u_{2}) u_{1} \\ + {T u_{1}, T u_{2}, T θ_{12} (T u_{3}, x) u_{4}}_{1} - T θ_{13} (T u_{1}, T θ_{12} (T u_{3}, x) u_{4}) u_{2} - T θ_{12} (T θ_{12} (T u_{3}, x) u_{4}, T u_{2}) u_{1} \end{array}$

$\begin{array}{l} - {T u_{3}, T u_{2}, {T u_{1}, x, T u_{4}}_{1}}_{1} + T θ_{13} (T u_{3}, {T u_{1}, x, T u_{4}}_{1}) u_{2} + T θ_{12} ({T u_{1}, x, T u_{4}}_{1}, T u_{2}) u_{3} \\ + {T u_{3}, T u_{2}, T θ_{12} (T u_{4}, x) u_{1}}_{1} - T θ_{13} (T u_{3}, T θ_{12} (T u_{4}, x) u_{1}) u_{2} - T θ_{12} (T θ_{12} (T u_{4}, x) u_{1}, T u_{2}) u_{3} \\ + {T u_{3}, T u_{2}, T θ_{12} (T u_{1}, x) u_{4}}_{1} - T θ_{13} (T u_{3}, T θ_{12} (T u_{1}, x) u_{4}) u_{2} - T θ_{12} (T θ_{12} (T u_{1}, x) u_{4}, T u_{2}) u_{3} \\ + {T u_{1}, {T u_{2}, T u_{4}, x}_{1}, T u_{3}}_{1} - T θ_{12} (T u_{3}, {T u_{2}, T u_{4}, x}_{1} u_{1}) - T θ_{12} (T u_{1}, {T u_{2}, T u_{4}, x}_{1}) u_{3} \end{array}$

$\begin{array}{l} - {T u_{1}, T θ_{13} (T u_{2}, x) u_{4}, T u_{3}}_{1} + T θ_{12} (T u_{3}, T θ_{13} (T u_{2}, x) u_{4}) u_{1} + T θ_{12} (T u_{1}, T θ_{13} (T u_{2}, x) u_{4}) u_{3} \\ - {T u_{1}, T θ_{12} (x, T u_{4}) u_{2}, T u_{3}}_{1} + T θ_{12} (T u_{3}, x) T θ_{12} (x, T u_{4}) u_{2} u_{1} + T θ_{12} (T u_{1}, T θ_{12} (x, T u_{4}) u_{2}) u_{3} \\ = {{T u_{1}, T u_{2}, T u_{3}}_{1}, x, T u_{4}}_{1} - {T u_{1}, T u_{2}, {T u_{3}, x, T u_{4}}_{1}}_{1} - {T u_{3}, T u_{2}, {T u_{1}, x, T u_{4}}_{1}}_{1} \\ + {T u_{1}, {T u_{2}, T u_{4}, x}_{1}, T u_{3}} - T (C_{41} u_{1} + C_{42} u_{2} + C_{43} u_{3} + C_{44} u_{4} + λ C_{45}) \end{array}$

其中，

$C_{41} = θ_{12} (T u_{4}, x) θ_{12} (T u_{3}, T u_{2}) - θ_{12} ({T u_{3}, x, T u_{4}}_{1}, T u_{2}) - θ_{12} (T u_{3}, T u_{2}) θ_{12} (T u_{4}, x) + θ_{12} (T u_{3}, {T u_{2}, T u_{4}, x}_{1})$ ，

$C_{42} = θ_{12} (T u_{4}, x) θ_{13} (T u_{1}, T u_{3}) - θ_{13} (T u_{1}, {T u_{3}, x, T u_{4}}_{1}) - θ_{13} (T u_{3}, {T u_{1}, x, T u_{4}}_{1}) + θ_{13} (T u_{1}, T u_{3}) θ_{12} (x, T u_{4})$ ，

$C_{43} = θ_{12} (T u_{4}, x) θ_{12} (T u_{1}, T u_{2}) - θ_{12} (T u_{1}, T u_{2}) θ_{12} (T u_{4}, x) - θ_{12} ({T u_{1}, x, T u_{4}}_{1}, T u_{2}) + θ_{12} (T u_{1}, {T u_{2}, T u_{4}, x}_{1})$ ，

$C_{44} = θ_{12} ({T u_{1}, T u_{2}, T u_{3}}_{1}, x) - θ_{12} (T u_{1}, T u_{2}) θ_{12} (T u_{3}, x) - θ_{12} (T u_{3}, T u_{2}) θ_{12} (T u_{1}, x) + θ_{13} (T u_{1}, T u_{3}) θ_{13} (T u_{2}, x)$ ，

$\begin{matrix} C_{45} = θ_{12} (T u_{4}, x) {u_{1}, u_{2}, u_{3}}_{2} - {u_{1}, u_{2}, θ_{12} (T u_{4}, x) u_{3}}_{2} - {u_{1}, u_{2}, θ_{12} (T u_{3}, x) u_{4}}_{2} - {u_{3}, u_{2}, θ_{12} (T u_{4}, x) u_{1}}_{2} \\ - {u_{3}, u_{2}, θ_{12} (T u_{1}, x) u_{4}}_{2} + {u_{1}, θ_{12} (x, T u_{4}) u_{2}, u_{3}}_{2} + {u_{1}, θ_{13} (T u_{2}, x) u_{4}, u_{3}}_{2} \end{matrix}$ ，

由于 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 是约当三系，故(1.2)式成立，由(2.2)式成立知C₄₁为零，由(2.3)式成立知C₄₂为零，由(2.2)式成立知C₄₃为零，由(2.4)式成立知C₄₄为零，由于 $θ_{12}, θ_{13}$ 是 $(J_{1}, {\cdot, \cdot, \cdot}_{1})$ 在 $(J_{2}, {\cdot, \cdot, \cdot}_{2})$ 上的作用，故有 $θ_{12} (T u_{4}, x) {u_{1}, u_{2}, u_{3}}_{2} = 0$ ， ${u_{1}, u_{2}, θ_{12} (T u_{4}, x) u_{3}}_{2} = 0$ ，类似可知C₄₅为零，故(2.5)式成立。

综上， $(L_{T}, M_{T}, J_{1})$ 是 $(J_{2}, {\cdot, \cdot, \cdot}_{T})$ 的表示。

5. 相对Rota-Baxter算子的构造

命题5.1 $(J, {\cdot, \cdot, \cdot})$ 是约当三系， $(σ_{12}, σ_{13}, J)$ 是 $(J, {\cdot, \cdot, \cdot})$ 的伴随表示， $J_{0}$ 是J的子系且满足 $J_{0}^{1} = {0}$ ， $J^{1} \cap J_{0} = {0}$ ， ${J_{0}, J_{0}, J} = {0}$ ， ${J_{0}, J, J_{0}} = {0}$ 。设H是 $J_{0}$ 的补空间，使 $J = H \oplus J_{0}$ ，P是J在 $J_{0}$ 上的自然投影，即

$P (x) = x_{0}, x \in J, x_{0} \in J_{0}$ ，

则P是关于作用 $σ_{12}, σ_{13}$ 的权为 $λ$ 的相对Rota-Baxter算子。

证：由于 $(σ_{12}, σ_{13}, J)$ 是 $(J, {\cdot, \cdot, \cdot})$ 的伴随表示，故由例2.2知， $σ_{12}, σ_{13}$ 是 $(J, {\cdot, \cdot, \cdot})$ 在自身上的作用， $\forall x, y, z \in J$ ，记 $x, y, z$ 在投影P下的像为 $x_{0}, y_{0}, z_{0}$ ，

$\begin{array}{l} {P x, P y, P z} - P (σ_{12} (P z, P y) x + σ_{13} (P x, P z) y + σ_{12} (P x, P y) z + λ {x, y, z}) \\ = {x_{0}, y_{0}, z_{0}} - P (σ_{12} (z_{0}, y_{0}) x + σ_{13} (x_{0}, z_{0}) y + σ_{12} (x_{0}, y_{0}) z + λ {x, y, z}) \\ = 0 \end{array}$ ，

所以，P是关于作用 $σ_{12}, σ_{13}$ 的权为 $λ$ 的相对Rota-Baxter算子。

例5.1 设 $(J, \cdot)$ 是三维约当代数， $n_{1}, n_{2}, n_{3}$ 是J的一组基，J中运算为

$n_{1} \cdot n_{1} = n_{2}, n_{2} \cdot n_{2} = 0, n_{3} \cdot n_{3} = 0, n_{1} \cdot n_{2} = n_{2} \cdot n_{1} = n_{3}, n_{1} \cdot n_{3} = n_{3} \cdot n_{1} = 0, n_{2} \cdot n_{3} = n_{3} \cdot n_{2} = 0$ 。

由例1.1知，在J上定义运算

${x, y, z} = (x \cdot y) \cdot z + (y \cdot z) \cdot x - (x \cdot z) \cdot y$ ，

则 $(J, {\cdot, \cdot, \cdot})$ 是约当三系，且基中元素的非零代数运算为

${n_{1}, n_{1}, n_{1}} = n_{3}$ ，

$(J, {\cdot, \cdot, \cdot})$ 的 $C (J)$ 是由 ${n_{2}, n_{3}}$ 生成的子系，则伴随表示 $(σ_{12}, σ_{13}, J)$ 是 $(J, {\cdot, \cdot, \cdot})$ 在自身上的一个作用。取 $J_{0}$ 为由 ${n_{2}}$ 所生成的子系，根据命题4.1，由

$P (n_{1}) = 0, P (n_{2}) = n_{2}, P (n_{3}) = 0$

所决定的投影 $P : J \to J_{0}$ 是关于作用 $σ_{12}, σ_{13}$ 的权为 $λ$ 的相对Rota-Baxter算子。

参考文献

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[4]	Erhard, N. (1983) Jordan Triple Forms of Jordan Alge-bras. Proceedings of the American Mathematical Society, 87, 386-388. https://doi.org/10.1090/S0002-9939-1983-0684623-0
[5]	Jiang, J., Sheng, Y.H. and Zhu, C.C. (2021) Lie Theory and Cohomology of Relative Rota-Baxter Operators.
[6]	Wu, X.R., Ma, Y. and Chen, L.Y. (2022) Relative Ro-ta-Baxter Operators of Nonzero Weights on Lie Triple Systems. arXiv: 2207.08946.
[7]	Albert, A.A. (1947) A Struc-ture Theory for Jordan Algebras. Annals of Mathematics, 48, 546-567. https://doi.org/10.2307/1969128
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