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{{{ _____________ / n Geometric Mean = n / __ / || Normalized(Pi) \/ i=1 |
[[latex2($$Geometric~Mean = \sqrt[n]{\prod_{i=1}^{n} Normalized(P_i)}$$)]] |
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where Normalized(Pi) = Pi / Pn where n is the referenced execution time. Obviously the geometic mean of the referenced machine is 1. |
where [[latex2($$Normalized(P_i) = \frac{P_i}{Pn}$$)]] where n is the referenced execution time. Obviously the geometic mean of the referenced machine is 1. |
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}}} | |
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{{{ GeometricMean(Xi) GeometricMean(Xi/Yi) = ------------------ GeometricMean(Yi) }}} |
[[latex2($$GeometricMean\left(\frac{X_i}{Y_i}\right) = \frac{GeometricMean(X_i)}{GeometricMean(Y_i)}$$)]] |
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The geometric mean of P1,..,Pn is
latex2($$Geometric~Mean = \sqrt[n]{\prod_{i=1}^{n} Normalized(P_i)}$$)
where latex2($$Normalized(P_i) = \frac{P_i}{Pn}$$) where n is the referenced execution time. Obviously the geometic mean of the referenced machine is 1.
One of the nice features of Geometric means is that the following property holds:
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