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Could someone verify the following absolute value inequalitiy:

$b_k < |\epsilon + L| \iff b_k < \epsilon + L $ and $bk < -(\epsilon+L) \iff -bk > (\epsilon +L)$

All together:

$-b_k > (\epsilon +L) > b_k$

Is there any further way to simplify this?

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    As David Mitra points out, but more nicely, the end inequality doesn't make sense. Let's get rid of the stuff in the middle, you are saying $b_k \lt -b_k$. Let $b_k=17$.2012-12-11

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I think it is correct. Further simplification would be dependent on whether you are seeking bounds for $L$ or for $\epsilon$:

You have $bk < (L+\epsilon) < -bk$, which is equivalent to

  • either $bk -L < \epsilon < -bk-L$ (in other words, $\epsilon \in (bk-L, -bk+L)$)
  • or, equivalently, $bk - \epsilon < L < -bk - \epsilon$ (in other words, $L \in (bk-\epsilon, -bk+\epsilon)$).