完全にスッキリしなくて何だか気持ち悪いのだけれど,いきなり自由度がとかいわれて$n-2$が出てくるのがいやなので,吉澤さんの本に従って話を進めてみる。
$\displaystyle \tilde{\sigma^2}_{y(x_i)} = \frac{1}{n}\sum_{i=i}^n \tilde{\varepsilon_i}^2 = \frac{1}{n}\sum_{i=i}^n \Bigl\{ a x_i + b - a_0 x_i - b_0 \Bigr\}^2$
これから,$f(x_i) = y(x_i) = a \bm{x_i} + b$として,独立変数$y_j$について,
$\displaystyle \tilde{\sigma^2}_{y(x_i)} = \sigma_y^2 \sum_{j=i}^n \Bigl\{ \frac{\partial a}{\partial y_j}\bm{x_i} + \frac{\partial b}{\partial y_j} \Bigr\}^2 = \frac{\sigma_y^2}{n^2 \Delta^2} \sum_{j=i}^n \Bigl\{ (x_j-\overline{x}) \bm{x_i} + ( \overline{x^2} -\overline{x} x_j ) \Bigr\}^2$
$\displaystyle = \frac{\sigma_y^2}{n^2 \Delta^2} \sum_{j=i}^n \Bigl\{ ( \bm{x_i}-\overline{x} ) x_j + ( \overline{x^2} - \overline{x} \bm{x_i} ) \Bigr\}^2$
$\displaystyle = \frac{\sigma_y^2}{n \Delta^2} \Bigl\{ \overline{x^2} ( \bm{x_i}-\overline{x} )^2 + 2 \overline{x} (\bm{x_i} - \overline{x})(\overline{x^2} -\overline{x} \bm{x_i}) + ( \overline{x^2} - \overline{x} \bm{x_i} )^2 \Bigr\}$
$\displaystyle = \frac{\sigma_y^2}{n \Delta^2} \Bigl\{ \bm{x_i}^2 ( \overline{x^2} - \overline{x}^2) + 2 \bm{x_i} (\overline{x}^3 - \overline{x^2} \overline{x}) + ( \overline{x^2}^2 - \overline{x^2} \overline{x}^2 ) \Bigr\}$
$\displaystyle = \frac{\sigma_y^2}{n \Delta} \Bigl\{ \bm{x_i}^2 - 2 \bm{x_i} \overline{x} + \overline{x^2} \Bigr\}$
添え字 $i$について平均すると,$\displaystyle \frac{1}{n}\sum_{i=1}^n \tilde{\sigma^2}_{y(x_i)} =\frac{\sigma_y^2}{n \Delta}\Bigl\{ \overline{x^2} - 2 \overline{x} \overline{x} + \overline{x^2} \Bigr\} = \frac{2 \sigma_y^2}{n}$
そこで,
$\displaystyle \sigma_y^2 =\frac{1}{n}\sum_{i=1}^n \Bigl\{ \delta_i^2 + \tilde{\varepsilon_i}^2 \Bigr\} = \frac{1}{n}\sum_{i=i}^n \delta_i^2 + \tilde{\sigma^2}_{y(x_i)} = \frac{1}{n} \sum_{i=1}^n \delta_i^2 + \frac{2 \sigma_y^2}{n}$
$\displaystyle \therefore \sigma_y^2 = \frac{1}{n-2}\sum_{i=1}^n \delta_i^2 = \frac{1}{n-2}\sum_{i=1}^n (y_i - a x_i -b )^2$
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