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The saddlepoint approximation method, initially proposed by Daniels (1954)^[1] is a specific example of the mathematical saddlepoint technique applied to statistics, in particular to the distribution of the sum of $N$ indipendent random variables. It provides a highly accurate approximation formula for any PDF or probability mass function of a distribution, based on the moment generating function. There is also a formula for the CDF of the distribution, proposed by Lugannani and Rice (1980)^[2].

Definition

If the moment generating function of a random variable $X$ is written as $M(t)=E\left[e^{tX}\right]$ and the cumulant generating function as $K(t)=\log(M(t))$ then the saddlepoint approximation to the PDF of a distribution $X$ is defined as^[1]:

{\hat {f}}_{X}(x)={\frac {1}{\sqrt {2\pi K''({\hat {s}})}}}\exp(K({\hat {s}})-{\hat {s}}x)\,\left(1+{\mathcal {R}}\right)

where ${\mathcal {R}}$ is a remainder term in the approximation^[1] and the saddlepoint approximation to the CDF is defined as^[1]:

{\hat {F}}_{X}(x)={\begin{cases}\Phi ({\hat {w}})+\phi ({\hat {w}})\left({\frac {1}{\hat {w}}}-{\frac {1}{\hat {u}}}\right)&{\text{for }}x\neq \mu \\{\frac {1}{2}}+{\frac {K'''(0)}{6{\sqrt {2\pi }}K''(0)^{3/2}}}&{\text{for }}x=\mu \end{cases}}

where ${\hat {s}}$ is the solution to $K'({\hat {s}})=x$ , ${\hat {w}}=\operatorname {sgn} {\hat {s}}{\sqrt {2({\hat {s}}x-K({\hat {s}}))}}$ , ${\hat {u}}={\hat {s}}{\sqrt {K''({\hat {s}})}}$ , and $\Phi (t)$ is the cumulative distribution function of a normal distribution, $\phi (t)$ the probability density function of a normal distribution and $\mu$ is the mean of the random variable $X$ :

$\mu \triangleq E\left(X\right)$ .

When the distribution is that of a sample mean, Lugannani and Rice's saddlepoint expansion for the cumulative distribution function $F(x)$ may be differentiated to obtain Daniels' saddlepoint expansion for the probability density function $f(x)$ (Routledge and Tsao, 1997). This result establishes the derivative of a truncated Lugannani and Rice series as an alternative asymptotic approximation for the density function $f(x)$ . Unlike the original saddlepoint approximation for $f(x)$ , this alternative approximation in general does not need to be renormalized.

References

Butler, Ronald W. (2007), Saddlepoint approximations with applications, Cambridge: Cambridge University Press, ISBN 9780521872508
Daniels, H. E. (1954), "Saddlepoint Approximations in Statistics", The Annals of Mathematical Statistics, 25 (4): 631–650, doi:10.1214/aoms/1177728652
Daniels, H. E. (1980), "Exact Saddlepoint Approximations", Biometrika, 67 (1): 59–63, doi:10.1093/biomet/67.1.59, JSTOR 2335316
Lugannani, R.; Rice, S. (1980), "Saddle Point Approximation for the Distribution of the Sum of Independent Random Variables", Advances in Applied Probability, 12 (2): 475–490, doi:10.2307/1426607, JSTOR 1426607, S2CID 124484743
Reid, N. (1988), "Saddlepoint Methods and Statistical Inference", Statistical Science, 3 (2): 213–227, doi:10.1214/ss/1177012906
Routledge, R. D.; Tsao, M. (1997), "On the relationship between two asymptotic expansions for the distribution of sample mean and its applications", Annals of Statistics, 25 (5): 2200–2209, doi:10.1214/aos/1069362394

^ ^a ^b ^c ^d Daniels, H. E. (1954-12). "Saddlepoint Approximations in Statistics". The Annals of Mathematical Statistics. 25 (4): 631–650. doi:10.1214/aoms/1177728652. ISSN 0003-4851. {{cite journal}}: Check date values in: |date= (help)
^ Lugannani, Robert; Rice, Stephen (1980-06). "Saddle point approximation for the distribution of the sum of independent random variables". Advances in Applied Probability. 12 (2): 475–490. doi:10.2307/1426607. ISSN 0001-8678. {{cite journal}}: Check date values in: |date= (help)

[:0-1] Daniels, H. E. (1954-12). "Saddlepoint Approximations in Statistics". The Annals of Mathematical Statistics. 25 (4): 631–650. doi:10.1214/aoms/1177728652. ISSN 0003-4851. {{cite journal}}: Check date values in: |date= (help)

[2] Lugannani, Robert; Rice, Stephen (1980-06). "Saddle point approximation for the distribution of the sum of independent random variables". Advances in Applied Probability. 12 (2): 475–490. doi:10.2307/1426607. ISSN 0001-8678. {{cite journal}}: Check date values in: |date= (help)

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-The saddlepoint approximation method, initially proposed by [[Henry Daniels (statistician)|Daniels]] (1954) is a specific example of the mathematical [[method_of_steepest_descent| saddlepoint ]] technique applied to [[statistics]]. It provides a highly accurate approximation formula for any [[Probability density function|PDF]] or probability mass function of a distribution, based on the [[Moment-generating_function | moment generating function]]. There is also a formula for the [[cumulative_distribution_function | CDF ]] of the distribution, proposed by Lugannani and Rice (1980).
+The saddlepoint approximation method, initially proposed by [[Henry Daniels (statistician)|Daniels]] (1954)<ref name=":0">{{Cite journal |last=Daniels |first=H. E. |date=1954-12 |title=Saddlepoint Approximations in Statistics |url=http://projecteuclid.org/euclid.aoms/1177728652 |journal=The Annals of Mathematical Statistics |language=en |volume=25 |issue=4 |pages=631–650 |doi=10.1214/aoms/1177728652 |issn=0003-4851}}</ref> is a specific example of the mathematical [[method_of_steepest_descent| saddlepoint ]] technique applied to [[statistics]], in particular to the distribution of the sum of <math>N</math> indipendent random variables. It provides a highly accurate approximation formula for any [[Probability density function|PDF]] or probability mass function of a distribution, based on the[[Moment-generating_function | moment generating function]]. There is also a formula for the [[cumulative_distribution_function | CDF ]] of the distribution, proposed by Lugannani and Rice (1980)<ref>{{Cite journal |last=Lugannani |first=Robert |last2=Rice |first2=Stephen |date=1980-06 |title=Saddle point approximation for the distribution of the sum of independent random variables |url=https://www.cambridge.org/core/journals/advances-in-applied-probability/article/saddle-point-approximation-for-the-distribution-of-the-sum-of-independent-random-variables/70A031DB905980CA675021C6D9BFFD21 |journal=Advances in Applied Probability |language=en |volume=12 |issue=2 |pages=475–490 |doi=10.2307/1426607 |issn=0001-8678}}</ref>.
 == Definition ==
-If the moment generating function of a distribution is written as <math>M(t)</math> and the cumulant generating function as <math>K(t) = \log(M(t))</math> then the saddlepoint approximation to the PDF of a distribution is defined as:
+If the moment generating function of a random variable <math>X</math> is written as <math>M(t)=E\left[e^{tX}\right]</math> and the [[cumulant generating function]] as <math>K(t) = \log(M(t))</math> then the saddlepoint approximation to the [[Probability density function|PDF]] of a distribution <math>X</math> is defined as<ref name=":0" />:
-:<math>\hat{f}(x) = \frac{1}{\sqrt{2 \pi K''(\hat{s})}} \exp(K(\hat{s}) - \hat{s}x) </math>
+:<math>\hat{f}_X (x) = \frac{1}{\sqrt{2 \pi K''(\hat{s})}} \exp(K(\hat{s}) - \hat{s}x) \,\left(1+\mathcal{R}\right) </math>
-and the saddlepoint approximation to the CDF is defined as:
+where <math>\mathcal{R}</math> is a remainder term in the approximation<ref name=":0" /> and the saddlepoint approximation to the CDF is defined as<ref name=":0" />:
-:<math>\hat{F}(x) = \begin{cases} \Phi(\hat{w}) + \phi(\hat{w})(\frac{1}{\hat{w}} - \frac{1}{\hat{u}}) & \text{for } x \neq \mu \\
+:<math>\hat{F}_X (x) = \begin{cases} \Phi(\hat{w}) + \phi(\hat{w})\left(\frac{1}{\hat{w}} - \frac{1}{\hat{u}}\right) & \text{for } x \neq \mu \\
                                          \frac{1}{2} + \frac{K'''(0)}{6 \sqrt{2\pi} K''(0)^{3/2}} & \text{for } x = \mu
                     \end{cases} </math>
-where <math>\hat{s}</math> is the solution to <math>K'(\hat{s}) = x</math>, <math>\hat{w} = \sgn{\hat{s}}\sqrt{2(\hat{s}x - K(\hat{s}))}</math> and <math>\hat{u} = \hat{s}\sqrt{K''(\hat{s})}</math>.
+where <math>\hat{s}</math> is the solution to <math>K'(\hat{s}) = x</math>, <math>\hat{w} = \sgn{\hat{s}}\sqrt{2(\hat{s}x - K(\hat{s}))}</math> ,<math>\hat{u} = \hat{s}\sqrt{K''(\hat{s})}</math>, and <math>\Phi(t)</math> is the [[cumulative distribution function]] of a [[normal distribution]], <math>\phi(t)</math> the [[probability density function]] of a normal distribution and <math>\mu</math> is the mean of the random variable <math>X</math>:
+<math>\mu \triangleq E \left(X\right)</math>.
 When the distribution is that of a sample mean, Lugannani and Rice's saddlepoint expansion for the cumulative distribution function <math>F(x)</math> may be differentiated to obtain Daniels' saddlepoint expansion for the probability density function <math>f(x)</math> (Routledge and Tsao, 1997). This result establishes the derivative of a truncated Lugannani and Rice series as an alternative asymptotic approximation for the density function <math>f(x)</math>. Unlike the original saddlepoint approximation for <math>f(x)</math>, this alternative approximation in general does not need to be renormalized.