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{{Short description|Statistics model}}
In [[statistics]], a '''linear probability model''' (LPM) is a special case of a [[binary regression]] model. Here the [[dependent and independent variables|dependent variable]] for each observation takes values which are either 0 or 1. The probability of observing a 0 or 1 in any one case is treated as depending on one or more [[dependent and independent variables|explanatory variables]]. For the "linear probability model", this relationship is a particularly simple one, and allows the model to be fitted by [[linear regression]].
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==Latent-variable formulation==
More formally, the LPM can arise from a latent-variable formulation (usually to be found in the [[econometrics]] literature
: <math>y^* = b_0+ \mathbf x'\mathbf b + \varepsilon,\;\; \varepsilon\mid \mathbf x\sim U(-a,a).</math>
The critical assumption here is that the error term of this regression is a symmetric around zero [[Continuous uniform distribution|uniform]] [[random variable]], and hence, of mean zero. The cumulative distribution function of <math>\varepsilon</math> here is <math>F_{\varepsilon|\mathbf x}(\varepsilon\mid \mathbf x) = \frac {\varepsilon + a}{2a}.</math>
Define the indicator variable <math> y = 1</math> if <math> y^* >0</math>, and zero otherwise, and consider the conditional probability
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:<math>\beta_0 = \frac {b_0+a}{2a},\;\; \beta=\frac{\mathbf b}{2a}.</math>
This method is a general device to obtain a conditional probability model of a binary variable: if we assume that the distribution of the error term is
== See also ==
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