📖 generic · 12th TN - English Medium · MATHEMATICS-VOLUME 1 · Page 247question

6.6 Jacobi’s Identity and Lagrange’s Identity

Chapter 8: Chapter 6 · MATHEMATICS-VOLUME 1

. Jacobi’s Identity and Lagrange’s Identity Theorem . (Jacobi’s identity) For any three vectors , , , a b c  we have + × Proof Using vector triple product expansion, we have  = ( a c b a b c  = ( b a c b c a ... ( ) ...

( ) a i a i b c i b c j b c b c k a b c k a b c b c a c b a b c a c b i b j a b c i c j c k a b c b c a b c k ´ ´ ´ ´ =- ´ Now, Vector Vector = ( c b a c a b Adding the above equations and using the scalar product of two vectors is commutative, we get + × Theorem . (Lagrange’s identity) For any four vectors , , , , a b c d we have ( ) ( a c a d b c b d Proof Since dot and cross can be interchanged in a scalar product, we get ) ( )) (( ) ) b d c b c d (by vector triple product expansion) = ( )( )( a c b d a d b c = a c a d b c b d Example . Prove that ] [ , , ] b b c c a b c Using the definition of the scalar triple product, we get ]   b b c c = ( ) {( ) ( )} ... ( ) By treating (  as the first vector in the vector triple product, we find ) (  = (( (( [ , , ] a c c a a b c c  .

Using this value in ( ), we get ] b b

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