多元多项式的特征列与零点的关系定理
下面这个定理来自《计算机代数》6.1三角列与特征列(王东明、夏壁灿著)
【定理】
设 C = [ C 1 , … , C r ] \mathbb{C =}\left\lbrack C_{1},\ldots,C_{r} \right\rbrack C=[C1,…,Cr]为多项式组 P ⊂ K [ x ] \mathbb{P \subset}\mathcal{K\lbrack}\mathbf{x}\rbrack P⊂K[x]的特征列,且命
I i = i n i ( C i ) P i = P ∪ { I i } i = 1 , … , r I_{i} = ini\left( C_{i} \right)\ \ \ \ \ \ \mathbb{P}_{i}\mathbb{= P \cup}\left\{ I_{i} \right\}\ \ \ \ \ i = 1,\ldots,r Ii=ini(Ci) Pi=P∪{Ii} i=1,…,r
I = i n i ( C ) = { I 1 , … , I r } \mathbb{I =}ini\left( \mathbb{C} \right) = \left\{ I_{1},\ldots,I_{r} \right\} I=ini(C)={I1,…,Ir}
则
Z e r o ( C \ I ) ⊂ Z e r o ( P ) ⊂ Z e r o ( C ) Zero\left( \mathbb{C\backslash I} \right) \subset Zero\left( \mathbb{P} \right) \subset Zero\left( \mathbb{C} \right) Zero(C\I)⊂Zero(P)⊂Zero(C)
Z e r o ( P ) = Z e r o ( C \ I ) ∪ ⋃ i = 1 r Z e r o ( P i ) Zero\left( \mathbb{P} \right) = Zero\left( \mathbb{C\backslash I} \right) \cup \bigcup_{i = 1}^{r}{Zero\left( \mathbb{P}_{i} \right)} Zero(P)=Zero(C\I)∪i=1⋃rZero(Pi)
在 K \mathcal{K} K以及 K \mathcal{K} K的任意扩域中成立
【证明】
- Z e r o ( C \ I ) ⊂ Z e r o ( P ) Zero\left( \mathbb{C\backslash I} \right) \subset Zero\left( \mathbb{P} \right) Zero(C\I)⊂Zero(P)
由于 C = [ C 1 , … , C r ] \mathbb{C =}\left\lbrack C_{1},\ldots,C_{r} \right\rbrack C=[C1,…,Cr]为多项式组 P ⊂ K [ x ] \mathbb{P \subset}\mathcal{K\lbrack}\mathbf{x}\rbrack P⊂K[x]的特征列,所以 p r e m ( P , C ) = { 0 } prem\left( \mathbb{P,C} \right) = \left\{ 0 \right\} prem(P,C)={0},也就是说对于任意 P ∈ P P \in \mathbb{P} P∈P,都有
I 1 q 1 … I r q r P = ∑ i = 1 r C i I_{1}^{q_{1}}\ldots I_{r}^{q_{r}}P = \sum_{i = 1}^{r}C_{i} I1q1…IrqrP=i=1∑rCi
而对于任意的 x ∈ Z e r o ( C \ I ) x \in Zero\left( \mathbb{C\backslash I} \right) x∈Zero(C\I),都有 x ∉ Z e r o ( I 1 q 1 … I r q r ) x \notin Zero\left( I_{1}^{q_{1}}\ldots I_{r}^{q_{r}} \right) x∈/Zero(I1q1…Irqr)且 x ∈ Z e r o ( C i ) x \in Zero\left( C_{i} \right) x∈Zero(Ci),那么 P = 0 P = 0 P=0,可得 x ∈ Z e r o ( P ) x \in Zero\left( \mathbb{P} \right) x∈Zero(P),即 Z e r o ( C \ I ) ⊂ Z e r o ( P ) Zero\left( \mathbb{C\backslash I} \right) \subset Zero\left( \mathbb{P} \right) Zero(C\I)⊂Zero(P)。
- Z e r o ( P ) ⊂ Z e r o ( C ) Zero\left( \mathbb{P} \right) \subset Zero\left( \mathbb{C} \right) Zero(P)⊂Zero(C)
根据特征列的定义,有 C ⊂ ⟨ P ⟩ \mathbb{C \subset}\left\langle \mathbb{P} \right\rangle C⊂⟨P⟩,也就是
C i = ∑ P ∈ P k P P C_{i} = \sum_{P \in \mathbb{P}}^{}{k_{P}P} Ci=P∈P∑kPP
所以,当多项式 P P P的值为 0 0 0时, C i C_{i} Ci必为 0 0 0,即 Z e r o ( P ) ⊂ Z e r o ( C ) Zero\left( \mathbb{P} \right) \subset Zero\left( \mathbb{C} \right) Zero(P)⊂Zero(C)。
- Z e r o ( P ) ⊂ Z e r o ( C \ I ) ∪ ⋃ i = 1 r Z e r o ( P i ) Zero\left( \mathbb{P} \right) \subset Zero\left( \mathbb{C\backslash I} \right) \cup \bigcup_{i = 1}^{r}{Zero\left( \mathbb{P}_{i} \right)} Zero(P)⊂Zero(C\I)∪⋃i=1rZero(Pi)
设 x ∈ Z e r o ( P ) x \in Zero\left( \mathbb{P} \right) x∈Zero(P),根据2,那么有 x ∈ Z e r o ( C ) x \in Zero\left( \mathbb{C} \right) x∈Zero(C)。
若 x ∈ Z e r o ( I ) x \in Zero\left( \mathbb{I} \right) x∈Zero(I),则 x ∈ ⋃ i = 1 r Z e r o ( I i ) x \in \bigcup_{i = 1}^{r}{Zero\left( I_{i} \right)} x∈⋃i=1rZero(Ii),又因为 x ∈ Z e r o ( P ) x \in Zero\left( \mathbb{P} \right) x∈Zero(P),所以 x ∈ ⋃ i = 1 r Z e r o ( P i ) x \in \bigcup_{i = 1}^{r}{Zero\left( \mathbb{P}_{i} \right)} x∈⋃i=1rZero(Pi);
若 x ∉ Z e r o ( I ) x \notin Zero\left( \mathbb{I} \right) x∈/Zero(I),结合 x ∈ Z e r o ( C ) x \in Zero\left( \mathbb{C} \right) x∈Zero(C),可得 x ∈ Z e r o ( C \ I ) x \in Zero\left( \mathbb{C\backslash I} \right) x∈Zero(C\I)。
结合上述两种情况的讨论,可得 Z e r o ( P ) ⊂ Z e r o ( C \ I ) ∪ ⋃ i = 1 r Z e r o ( P i ) Zero\left( \mathbb{P} \right) \subset Zero\left( \mathbb{C\backslash I} \right) \cup \bigcup_{i = 1}^{r}{Zero\left( \mathbb{P}_{i} \right)} Zero(P)⊂Zero(C\I)∪⋃i=1rZero(Pi)。
- Z e r o ( P ) ⊃ Z e r o ( C \ I ) ∪ ⋃ i = 1 r Z e r o ( P i ) Zero\left( \mathbb{P} \right) \supset Zero\left( \mathbb{C\backslash I} \right) \cup \bigcup_{i = 1}^{r}{Zero\left( \mathbb{P}_{i} \right)} Zero(P)⊃Zero(C\I)∪⋃i=1rZero(Pi)
根据1, Z e r o ( C \ I ) ⊂ Z e r o ( P ) Zero\left( \mathbb{C\backslash I} \right) \subset Zero\left( \mathbb{P} \right) Zero(C\I)⊂Zero(P);
因为 Z e r o ( P i ) ⊂ Z e r o ( P ) Zero\left( \mathbb{P}_{i} \right) \subset Zero\left( \mathbb{P} \right) Zero(Pi)⊂Zero(P),所以 ⋃ i = 1 r Z e r o ( P i ) ⊂ Z e r o ( P ) \bigcup_{i = 1}^{r}{Zero\left( \mathbb{P}_{i} \right)} \subset Zero\left( \mathbb{P} \right) ⋃i=1rZero(Pi)⊂Zero(P)。
综合可得 Z e r o ( C \ I ) ∪ ⋃ i = 1 r Z e r o ( P i ) ⊂ Z e r o ( P ) Zero\left( \mathbb{C\backslash I} \right) \cup \bigcup_{i = 1}^{r}{Zero\left( \mathbb{P}_{i} \right)} \subset Zero\left( \mathbb{P} \right) Zero(C\I)∪⋃i=1rZero(Pi)⊂Zero(P)
综合1、2可得
Z e r o ( C \ I ) ⊂ Z e r o ( P ) ⊂ Z e r o ( C ) Zero\left( \mathbb{C\backslash I} \right) \subset Zero\left( \mathbb{P} \right) \subset Zero\left( \mathbb{C} \right) Zero(C\I)⊂Zero(P)⊂Zero(C)
综合3、4可得
Z e r o ( P ) = Z e r o ( C \ I ) ∪ ⋃ i = 1 r Z e r o ( P i ) Zero\left( \mathbb{P} \right) = Zero\left( \mathbb{C\backslash I} \right) \cup \bigcup_{i = 1}^{r}{Zero\left( \mathbb{P}_{i} \right)} Zero(P)=Zero(C\I)∪i=1⋃rZero(Pi)