$ \vec{\mu} = g \gamma \vec{S} $

&mu = g * gamma * &S

$ {\cal H} =- g \gamma \displaystyle\sum_{ j =1}^ N \vec{S}_j \cdot \vec{H}_0 $

cH = - g * gamma *@SUM( &S_j * &H_0 , j ,1 , N )

$ {\cal H}_{jk} =-2 J \vec{S}_j \cdot \vec{S}_k $

cH_jk =-2* J &S_j * &S_k

$ {\cal H} =\displaystyle\frac{1}{2}\left(-2 J \sum_ j ^ N \sum_ k ^ n \vec{S}_j \cdot \vec{S}_k \right)$

cH =-2* J *@SUM(@SUM( &S_j * &S_k , k , 1 , n ), j , 1 , N )/2

$ {\cal H}_0 =- \vec{\mu} \cdot \vec{H}_0 $

cal H_0 =- &mu * &H_0

$ E_0 =- g \gamma H_0 S_z $

E_0 =- g * gamma * H_0 * S_z

$ {\cal H}_0 =- g \gamma \vec{S} \cdot \vec{H}_0 $

cal H_0 =- g * gamma * &S * &H_0

$ E_0 =- g \gamma H_0 \displaystyle\sum_{ j =1}^ N S_{zj} $

E_0 =- g * gamma * H_0 *SUM( S_{zj} , j , 1 , N )

$ E_m =-2 J \displaystyle\sum_ j ^ N \sum_ k ^ n S_{jz} S_{kz} $

E_m =-2* J @SUM( @SUM( S_jz * S_kz , k , 1 , n ), j , 1 , N )

$ E =- g \gamma H_0 \displaystyle\sum_{ j =1}^ N S_{jz} -2 J \displaystyle\sum_{ j =1}^ N \displaystyle\sum_{ k =1}^ n S_{jz} S_{kz} $

E =- g * gamma * H_0 *@SUM( S_jz -2* J *@SUM( S_jz * S_kz , k , 1 , n), j , N )