$ \eta\equiv-\displaystyle\frac{1}{N}\left(V_0+\displaystyle\frac{1}{2}\displaystyle\sum_{ r = 1}^{3 N }\hbar\omega_r\right)$

eta =-(1/ N )*( V_0 +(1/2)*@SUM( hbar * omega_r , r , 1 , 3* N ))

$ Z =\displaystyle\sum_{n_1,n_2,\ldots,3 N }e^{ \beta \eta - \beta \sum_{ r =1}^{3 N } n_r \hbar \omega_r }$

Z =@SUM( exp( beta * eta - beta *@SUM( hbar * omega_r , r , 0 , n_r )), n_1 ,n_2 , ..., 3* N )

$\ln Z=\beta N\eta-\displaystyle\int_0^{\infty}d\omega\ln(1-e^{-\beta\hbar\omega})\sigma(\omega)$

ln Z=beta*N*eta-int_0^infty domega*ln(1-e^(-beta*hbar*omega))*sigma(omega)

$ H = V_0 +\displaystyle\frac{1}{2}\sum_{ r = 1}^{3 N } m ( \dot{q}_r ^2+ \omega_r ^2 q_r ^2)$

H = V_0 +(1/2)* m *@SUM( vq_r ^2+ omega_r ^2 q_r ^2 , r , 1 , 3* N )

$ \epsilon_r =\left( n_r +\displaystyle\frac{1}{2}\right) \hbar \omega_r $

epsilon_r =( n_r +1/2)* hbar * omega_r

$ E_{n_1,n_2,\ldots,n_{3N}} = V_0 +\displaystyle\sum_{ r =1}^{3 N }\left( n_r +\displaystyle\frac{1}{2}\right) \hbar \omega_r $

E_n1n2n3N = V_0 +@SUM(( n_r +1/2)* hbar * omega_r , r , 0 , 3* N )

$ Z =e^{ \beta \eta N }\displaystyle\prod_{ r = 1}^{3 N }\left(\displaystyle\sum_{ n_r =0}^{\infty}e^{- \beta n_r \hbar \omega_r }\right)$

Z =exp( beta * eta * N )*@PROD(@SUM( exp(- beta * n_r * hbar * omega_r ), n_r , 0 , infty ), r , 0, 3 N )

$Z=e^{ \beta \eta N }\displaystyle\prod_{ r =1}^{3 N }\left(\displaystyle\frac{1}{1-e^{- \beta \hbar \omega_r }}\right)$

Z=e^( beta * eta * N )*@PROD(1/(1-e^(- beta * hbar * omega_r )), r , 1 , 3* N )

$ \ln Z = \beta N \eta -\displaystyle\sum_{ r =1}^{3 N }\ln(1-e^{- \beta \hbar \omega_r })$

ln Z = beta * N * eta -@SUM( ln(1-exp(- beta * hbar *omega_r ), r , 1 , 3* N )

$ \eta \equiv - \displaystyle\frac{1}{ N }\left( V_0 + \displaystyle\frac{1}{2} \int_0^{\infty} \hbar \omega \sigma( \omega ) d \omega \right)$

eta = -( V_0 + @INT( hbar * omega * sigma , omega , 0 , infty )/2)/ N