where is a twice-differentiablefunction, is a large number, and the endpoints and could be infinite. This technique was originally presented in the book by Laplace (1774).
Let the function have a unique global maximum at . is a constant here. The following two functions are considered:
Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "http://localhost:6011/en.wikipedia.org/v1/":): {\displaystyle \begin{align} g(x) &= Mf(x), \\ h(x) &= e^{Mf(x)}. \end{align}}
Then, is the global maximum of and as well. Hence:
As M increases, the ratio for will grow exponentially, while the ratio for does not change. Thus, significant contributions to the integral of this function will come only from points in a neighborhood of , which can then be estimated.
To state and motivate the method, one must make several assumptions. It is assumed that is not an endpoint of the interval of integration and that the values cannot be very close to unless is close to .
Since has a global maximum at , and is not an endpoint, it is a stationary point, i.e. . Therefore, the second-order Taylor polynomial approximating is
Then, just one more step is needed to get a Gaussian distribution. Since is a global maximum of the function it can be stated, by definition of the second derivative, that , thus giving the relation
for close to . The integral can then be approximated with:
If this latter integral becomes a Gaussian integral if we replace the limits of integration by and ; when is large this creates only a small error because the exponential decays very fast away from . Computing this Gaussian integral we obtain:
A generalization of this method and extension to arbitrary precision is provided by the book Fog (2008).
Suppose is a twice continuously differentiable function on and there exists a unique point such that:
Then:
Proof
Lower bound: Let . Since is continuous there exists such that if then By Taylor's Theorem, for any
Then we have the following lower bound:
where the last equality was obtained by a change of variables
Remember so we can take the square root of its negation.
If we divide both sides of the above inequality by
and take the limit we get:
since this is true for arbitrary we get the lower bound:
Note that this proof works also when or (or both).
Upper bound: The proof is similar to that of the lower bound but there are a few inconveniences. Again we start by picking an but in order for the proof to work we need small enough so that Then, as above, by continuity of and Taylor's Theorem we can find so that if , then
Lastly, by our assumptions (assuming are finite) there exists an such that if , then .
Then we can calculate the following upper bound:
If we divide both sides of the above inequality by
and take the limit we get:
Since is arbitrary we get the upper bound:
And combining this with the lower bound gives the result.
Note that the above proof obviously fails when or (or both). To deal with these cases, we need some extra assumptions. A sufficient (not necessary) assumption is that for
and that the number as above exists (note that this must be an assumption in the case when the interval is infinite). The proof proceeds otherwise as above, but with a slightly different approximation of integrals:
When we divide by
we get for this term
whose limit as is . The rest of the proof (the analysis of the interesting term) proceeds as above.
The given condition in the infinite interval case is, as said above, sufficient but not necessary. However, the condition is fulfilled in many, if not in most, applications: the condition simply says that the integral we are studying must be well-defined (not infinite) and that the maximum of the function at must be a "true" maximum (the number must exist). There is no need to demand that the integral is finite for but it is enough to demand that the integral is finite for some
This method relies on 4 basic concepts such as
Concepts
1. Relative error
The “approximation” in this method is related to the relative error and not the absolute error. Therefore, if we set
the integral can be written as
where is a small number when is a large number obviously and the relative error will be
Now, let us separate this integral into two parts: region and the rest.
Let’s look at the Taylor expansion of around x0 and translate x to y because we do the comparison in y-space, we will get
Note that because is a stationary point. From this equation you will find that the terms higher than second derivative in this Taylor expansion is suppressed as the order of so that will get closer to the Gaussian function as shown in figure. Besides,
3. The larger is, the smaller range of is related
Because we do the comparison in y-space, is fixed in which will cause ; however, is inversely proportional to , the chosen region of will be smaller when is increased.
4. If the integral in Laplace's method converges, the contribution of the region which is not around the stationary point of the integration of its relative error will tend to zero as grows.
Relying on the 3rd concept, even if we choose a very large Dy, sDy will finally be a very small number when is increased to a huge number. Then, how can we guarantee the integral of the rest will tend to 0 when is large enough?
The basic idea is to find a function such that and the integral of will tend to zero when grows. Because the exponential function of will be always larger than zero as long as is a real number, and this exponential function is proportional to the integral of will tend to zero. For simplicity, choose as a tangent through the point as shown in the figure:
If the interval of the integration of this method is finite, we will find that no matter is continue in the rest region, it will be always smaller than shown above when is large enough. By the way, it will be proved later that the integral of will tend to zero when is large enough.
If the interval of the integration of this method is infinite, and might always cross to each other. If so, we cannot guarantee that the integral of will tend to zero finally. For example, in the case of will always diverge. Therefore, we need to require that can converge for the infinite interval case. If so, this integral will tend to zero when is large enough and we can choose this as the cross of and
You might ask why not choose as a convergent integral? Let me use an example to show you the reason. Suppose the rest part of is then and its integral will diverge; however, when the integral of converges. So, the integral of some functions will diverge when is not a large number, but they will converge when is large enough.
Based on these four concepts, we can derive the relative error of this method.
Importantly, the accuracy of the approximation depends on the variable of integration, that is, on what stays in and what goes into [3]
The derivation of its relative error
First, use to denote the global maximum, which will simplify this derivation. We are interested in the relative error, written as ,
where
So, if we let
and , we can get
since .
For the upper bound, note that thus we can separate this integration into 5 parts with 3 different types (a), (b) and (c), respectively. Therefore,
where and are similar, let us just calculate and and are similar, too, I’ll just calculate .
For , after the translation of , we can get
This means that as long as is large enough, it will tend to zero.
For , we can get
where
and should have the same sign of during this region. Let us choose as the tangent across the point at , i.e. which is shown in the figure
From this figure you can find that when or gets smaller, the region satisfies the above inequality will get larger. Therefore, if we want to find a suitable to cover the whole during the interval of , will have an upper limit. Besides, because the integration of is simple, let me use it to estimate the relative error contributed by this .
Based on Taylor expansion, we can get
and
and then substitute them back into the calculation of ; however, you can find that the remainders of these two expansions are both inversely proportional to the square root of , let me drop them out to beautify the calculation. Keeping them is better, but it will make the formula uglier.
Therefore, it will tend to zero when gets larger, but don't forget that the upper bound of should be considered during this calculation.
About the integration near , we can also use Taylor's Theorem to calculate it. When
and you can find that it is inversely proportional to the square root of . In fact, will have the same behave when is a constant.
Conclusively, the integral near the stationary point will get smaller as gets larger, and the rest parts will tend to zero as long as is large enough; however, we need to remember that has an upper limit which is decided by whether the function is always larger than in the rest region. However, as long as we can find one satisfying this condition, the upper bound of can be chosen as directly proportional to since is a tangent across the point of at . So, the bigger is, the bigger can be.
In the multivariate case, where is a -dimensional vector and is a scalar function of , Laplace's approximation is usually written as:
In extensions of Laplace's method, complex analysis, and in particular Cauchy's integral formula, is used to find a contour of steepest descent for an (asymptotically with large M) equivalent integral, expressed as a line integral. In particular, if no point x0 where the derivative of vanishes exists on the real line, it may be necessary to deform the integration contour to an optimal one, where the above analysis will be possible. Again, the main idea is to reduce, at least asymptotically, the calculation of the given integral to that of a simpler integral that can be explicitly evaluated. See the book of Erdelyi (1956) for a simple discussion (where the method is termed steepest descents).
The appropriate formulation for the complex z-plane is
for a path passing through the saddle point at z0. Note the explicit appearance of a minus sign to indicate the direction of the second derivative: one must not take the modulus. Also note that if the integrand is meromorphic, one may have to add residues corresponding to poles traversed while deforming the contour (see for example section 3 of Okounkov's paper Symmetric functions and random partitions).
An extension of the steepest descent method is the so-called nonlinear stationary phase/steepest descent method. Here, instead of integrals, one needs to evaluate asymptotically solutions of Riemann–Hilbert factorization problems.
Given a contour C in the complex sphere, a function defined on that contour and a special point, such as infinity, a holomorphic function M is sought away from C, with prescribed jump across C, and with a given normalization at infinity. If and hence M are matrices rather than scalars this is a problem that in general does not admit an explicit solution.
An asymptotic evaluation is then possible along the lines of the linear stationary phase/steepest descent method. The idea is to reduce asymptotically the solution of the given Riemann–Hilbert problem to that of a simpler, explicitly solvable, Riemann–Hilbert problem. Cauchy's theorem is used to justify deformations of the jump contour.
The nonlinear stationary phase was introduced by Deift and Zhou in 1993, based on earlier work of Its. A (properly speaking) nonlinear steepest descent method was introduced by Kamvissis, K. McLaughlin and P. Miller in 2003, based on previous work of Lax, Levermore, Deift, Venakides and Zhou. As in the linear case, "steepest descent contours" solve a min-max problem. In the nonlinear case they turn out to be "S-curves" (defined in a different context back in the 80s by Stahl, Gonchar and Rakhmanov).
In general, any distribution diffeomorphic to the Gaussian distribution has density
and the median-point is mapped to the median of the Gaussian distribution. Matching the logarithm of the density functions and their derivatives at the median point up to a given order yields a system of equations that determine the approximate values of and .
The approximation was introduced in 2019 by D. Makogon and C. Morais Smith primarily in the context of partition function evaluation for a system of interacting fermions.[5]
with we make the substitution t = iu and the change of variable to get the bilateral Laplace transform:
We then split g(c + ix) in its real and complex part, after which we recover u = t/i. This is useful for inverse Laplace transforms, the Perron formula and complex integration.
^Tierney, Luke; Kadane, Joseph B. (1986). "Accurate Approximations for Posterior Moments and Marginal Densities". J. Amer. Statist. Assoc. 81 (393): 82–86. doi:10.1080/01621459.1986.10478240.
^Amaral Turkman, M. Antónia; Paulino, Carlos Daniel; Müller, Peter (2019). "Methods Based on Analytic Approximations". Computational Bayesian Statistics: An Introduction. Cambridge University Press. pp. 150–171. ISBN978-1-108-70374-1.
^Butler, Ronald W (2007). Saddlepoint approximations and applications. Cambridge University Press. ISBN978-0-521-87250-8.
Azevedo-Filho, A.; Shachter, R. (1994), "Laplace's Method Approximations for Probabilistic Inference in Belief Networks with Continuous Variables", in Mantaras, R.; Poole, D. (eds.), Uncertainty in Artificial Intelligence, San Francisco, CA: Morgan Kaufmann, CiteSeerX10.1.1.91.2064.
Deift, P.; Zhou, X. (1993), "A steepest descent method for oscillatory Riemann–Hilbert problems. Asymptotics for the MKdV equation", Ann. of Math., vol. 137, no. 2, pp. 295–368, arXiv:math/9201261, doi:10.2307/2946540, JSTOR2946540.
Erdelyi, A. (1956), Asymptotic Expansions, Dover.
Fog, A. (2008), "Calculation Methods for Wallenius' Noncentral Hypergeometric Distribution", Communications in Statistics, Simulation and Computation, vol. 37, no. 2, pp. 258–273, doi:10.1080/03610910701790269, S2CID9040568.
Laplace, P S (1774), "Mémoires de Mathématique et de Physique, Tome Sixième" [Memoir on the probability of causes of events.], Statistical Science, 1 (3): 366–367, JSTOR2245476