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The earliest Revenue Management model is known as Littlewood’s rule.

The two class model

Littlewood proposed the first static single resource quantity based RM model.^[1] It was a solution method for the seat inventory problem for a single leg flight with two fare classes. Those two fare classes have a fare of ${\displaystyle R_1}$ and ${\displaystyle R_2}$, whereby ${\displaystyle R_1>R_2}$. The total capacity is ${\displaystyle C}$ and demand for class ${\displaystyle j}$ is indicated with ${\displaystyle D_j}$. The demand is distributed via a distribution that is indicated with ${\displaystyle F_j()}$. The demand for class 2 comes before demand for class 1. The question now is how much demand for class 2 should be accepted so that the optimal mix of passengers is achieved and the highest revenue is obtained. Littlewood suggests closing down class 2 when the certain revenue from selling another low fare seat is exceeded by the expected revenue of selling the same seat at the higher fare.^[2] In formula form this means: accept demand for class 2 as long as:

${\displaystyle R_2\ge R_1*\text{Prob}(D_1>x)}$

where

${\displaystyle R_2}$ is the value of the lower valued segment

${\displaystyle R_1}$ is the value of the higher valued segment

${\displaystyle D_1}$ is the demand for the higher valued segment and

${\displaystyle x}$ is the capacity left

This suggests that there is an optimal protection limit ${\displaystyle y_1^{\star }}$. If the capacity left is less than this limit demand for class 2 is rejected. If a continuous distribution ${\displaystyle F_j(x)}$ is used to model the demand, then ${\displaystyle y_1^{\star }}$ can be calculated using what is called Littlewood’s rule:

${\displaystyle y_1^{\star }=F_1^{-1}(1-\frac{R_2}{R_1})}$

This gives the optimal protection limit, in terms of the division of the marginal revenue of both classes.

Alternatively bid prices can be calculated via

${\displaystyle \pi (x)=R_1*\text{Prob}(D_1>x)}$

Littlewood's model is limited to two classes. P. Belobaba developed a model based on this rule called Expected marginal seat revenue, abbreviated as EMSR, which is an ${\displaystyle n}$-class model ^[3]

References

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See also

• Yield management
• Expected marginal seat revenue