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:<math>W^G = \sum_{t=1}^{\infty} \delta^{t-1}(q_t(1-S) + r_t(1-2S)\,</math>
 
:<math>\therefore W^G = (1-S) - \left (1 - \frac{p(2-p)}{1-\delta(1-p)^2}\right)(1-S) - \frac{p^2}{1-\delta(1-p)^2}S\,</math>
:<math>\therefore W^G = (1-S) - \underbrace{\left (1 - \frac{p(2-p)}{1-\delta(1-p)^2}\right)(1-S)}_{\mbox{Delay Loss}} - \underbrace{\frac{p^2}{1-\delta(1-p)^2}S}_{\mbox{Duplication Loss}}\,</math>
This can be written as the difference from the first-best:
 
:<math>W^* - W^D = q^2 S_L + (1-q)^2\delta \cdot\frac{p^2}{1-\delta(1-p}^2)S_H + \left (1-q)^2\delta \cdot(1 - \frac{p(2-p)}{1-\delta(1-p)^2}\right)(1-S_H)\,</math>
:<math>W^* - W^D = \underbrace{q^2 S_L + (1-q)^2\delta \cdot\frac{p^2}{1-\delta(1-p)^2}S_H}_{\mbox{Duplication Loss}} + \underbrace{\left (1-q)^2\delta \cdot(1 - \frac{p(2-p)}{1-\delta(1-p)^2}\right)(1-S_H)}_{\mbox{Delay Loss}}\,</math>
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