# MC Integration ## Classical Monte Carlo Integration [Robert and Casella (2013)](https://www.springer.com/gp/book/9781475730715) introduces the classical Monte Carlo integration: ![](https://666993855-files.gitbook.io/~/files/v0/b/gitbook-legacy-files/o/assets%2F-LJfsESZOIJn_3uGIecs%2F-LKpSQx4NCkPqeJF51AF%2F-LKpSRNiaTJ1_q9CwinA%2Fclassical-mc.png?generation=1535273978327714\&alt=media) ## Toy Example 为了计算积分 ![](https://latex.codecogs.com/gif.latex?I%20%3D%20\int%20_D%20g\(\mathbf%20x\)d\mathbf%20x) 我们通常采用MC模拟: 1. 计算区域的volume:![](https://latex.codecogs.com/gif.latex?V%20%3D%20\int_D%20d\mathbf%20x) 2. 近似:![](https://latex.codecogs.com/gif.latex?\hat%20I_m%3DV\frac{1}{m}\sum\limits_{i%3D1}^mg\(\mathbf%20x^{\(m\)}\)) 根据大数律有 ![](https://latex.codecogs.com/gif.latex?\lim_{m\rightarrow%20\infty}%20\hat%20I_m%3DI) 并且由中心极限定理有 ![](https://latex.codecogs.com/gif.latex?\frac{1}{V}{}\sqrt{m}\(\hat%20I_m-I\)\rightarrow%20N\(0%2C%20\sigma^2\)) 其中![](https://latex.codecogs.com/gif.latex?\sigma^2%3Dvar\(g\(\mathbf%20x\)\)) 另外,注意到 $$ I = \int\_Dg(\mathbf x)d\mathbf x = \int\_D Vg(\mathbf x)\frac 1V d\mathbf x = {\mathbb E}\_f\[Vg(\mathbf x)], $$ 则可以直接利用上一节的结论。 ```r ## estimate pi ## ## I = \int H(x, y)dxdy ## where H(x, y) = 1 when x^2+y^2 <= 1; ## otherwise H(x, y) = 0 ## volume V = 4 n = 100000 x = runif(n, -1, 1) y = runif(n, -1, 1) H = x^2+y^2 H[H<=1] = 1 H[H>1] = 0 I = V* mean(H) cat("I = ", I, "\n") ## n = 100, I = 2.96 ## n = 1000, I = 3.22 ## n = 10000, I = 3.1536 ## n = 100000, I = 3.14504 ``` ## Polar Simulation **Note:** Unless otherwise stated, the algorithms and the corresponding screenshots are adopted from [Robert and Casella (2013)](https://www.springer.com/gp/book/9781475730715). ![](https://666993855-files.gitbook.io/~/files/v0/b/gitbook-legacy-files/o/assets%2F-LJfsESZOIJn_3uGIecs%2F-LKMsKp0fiNlRYE2Kl_s%2F-LKMsLEeSF7XE9PMfmNF%2Fex-3-2-2.png?generation=1534777714582544\&alt=media) ![](https://666993855-files.gitbook.io/~/files/v0/b/gitbook-legacy-files/o/assets%2F-LJfsESZOIJn_3uGIecs%2F-LKMsKp0fiNlRYE2Kl_s%2F-LKMsLEgZXntbVr41_Yg%2Fpolar-simulation.png?generation=1534777714606706\&alt=media) The following Julia program can be used to do polar simulation. ```julia using Statistics function polarsim(x::Array) while true phi1 = rand()*2*pi phi2 = rand()*pi - pi/2 u = rand() xdotxi = x[1]*cos(phi1) + x[2]*sin(phi1)*cos(phi2) + x[3]*sin(phi1)*sin(phi2) if u <= exp(xdotxi - sum(x.^2)/2) return(randn() + xdotxi) end end end # approximate E^pi function Epi(m, x = [0.1, 1.2, -0.7]) rhos = ones(m) for i = 1:m rhos[i] = 1/(2*polarsim(x)^2+3) end return(mean(rhos)) end # example Epi(10) ```