# Independent MH ## Gamma distribution [Robert and Casella (2013)](https://www.springer.com/gp/book/9781475730715) presents the following algorithm: ![](/files/-LXMjdqTiUn6bWWLB-Bn) If there exists a constant $$M$$ such that $$ f(x) \le Mg(x),,\qquad \forall x\in \mathrm{supp};f,, $$ the algorithm produces a uniformly ergodic chain ([Theorem](https://github.com/szcf-weiya/MonteCarlo/tree/187b2dfe70ab6f2954aa7cd9355579e90a9886e1/MH/IMH/thm_imh.png)), and the expected acceptance probability associated with the algorithm is at least $$1/M$$ when the chain is stationary, and in that sense, the IMH is more efficient than the Accept-Reject algorithm. Let's illustrate this algorithm with $${\mathcal G}a(\alpha, 1)$$. We have introduced how to sample from Gamma distribution via Accept-Reject algorithm in [Special Distributions](https://mc.hohoweiya.xyz/genrv/special), and it is straightforward to get the Gamma Metropolis-Hastings based on the ratio of $$f/g$$, ![](/files/-LXMjdqWynOfTtyTJGFj) And we can implement this algorithm with the Julia code: ```julia function mh_gamma(T = 100, alpha = 1.5) a = Int(floor(alpha)) b = a/alpha x = ones(T+1) # initial value: 1 for t = 1:T yt = rgamma_int(a, b) rt = (yt / x[t] * exp((x[t] - yt) / alpha))^(alpha-a) if rt >= 1 x[t+1] = yt else u = rand() if u < rt x[t+1] = yt else x[t+1] = x[t] end end end return(x) end ``` To sample $${\mathcal G}a(2.43, 1)$$, and estimate $$\mathrm{E}\_f(X^2)=2.43+2.43^2=8.33$$. ```julia # comparison with accept-reject res = mh_gamma(5000, 2.43)[2:end] est = cumsum(res.^2) ./ collect(1:5000) res2 = ones(5000) for i = 1:5000 res2[i] = rgamma(2.43, 1) end est2 = cumsum(res2.^2) ./ collect(1:5000) using Plots plot(est, label="Independent MH") plot!(est2, label="Accept-Reject") hline!([8.33], label="True value") ``` ![](/files/-LXMjdq_-7Rxi1_cUrcJ) ## Logistic Regression We observe $$(x\_i,y\_i),i=1,\ldots,n$$ according to the model $$ Y\_i\sim\mathrm{Bernoulli}(p(x\_i)),,\qquad p(x) = \frac{\exp(\alpha+\beta x)}{1+\exp(\alpha+\beta x)},. $$ The likelihood is $$ L(\alpha,\beta\mid \mathbf y) \propto \prod\_{i=1}^n \Big(\frac{\exp(\alpha+\beta x\_i)}{1+\exp(\alpha+\beta x\_i)}\Big)^{y\_i}\Big(\frac{1}{1+\exp(\alpha+\beta x\_i)}\Big)^{1-y\_i} $$ and let $$\pi(e^\alpha)\sim \mathrm{Exp}(1/b)$$ and put a flat prior on $$\beta$$, i.e., $$ \pi\_\alpha(\alpha\mid b)\pi\_\beta(b) = \frac 1b e^{-e^\alpha/b}de^\alpha d\beta=\frac 1b e^\alpha e^{-e^\alpha/b}d\alpha d\beta,. $$ Note that $$ \begin{aligned} \mathrm{E}\[\alpha] &= \int\_{-\infty}^\infty \frac{\alpha}{b}e^\alpha e^{-e^\alpha/b}d\alpha\\ &=\int\_0^\infty \log w\frac 1b e^{-w/b} \\ &=\log b -\gamma,, \end{aligned} $$ where $$ \gamma = -\int\_0^\infty e^{-x}\log xdx $$ is the [Euler's Constant](https://en.wikipedia.org/wiki/Euler–Mascheroni_constant). Choose the data-dependent value that makes $$\mathrm{E}\alpha=\hat\alpha$$, where $$\hat \alpha$$ is the MLE of $$\alpha$$, so $$\hat b=\exp(\hat \alpha+\gamma)$$. We can use MLE to estimate the coefficient in the logistical model (see [my post](https://stats.hohoweiya.xyz/2017/07/30/Estimate-Parameters-in-Logistic-Regression/) for the derivation), and the following Julia code can help us fit the model quickly. ```julia using DataFrames, GLM, Plots temp = [53, 57, 58, 63, 66, 67, 67, 67, 68, 69, 70, 70, 70, 70, 72, 73, 75, 75, 76, 76, 78, 79, 81] failure = [1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 0, 0, 0, 1, 0, 0, 0, 0, 0] data = DataFrame(temp = temp, failure = failure) logit_fit = glm(@formula(failure ~ temp), data, Binomial(), LogitLink()) plot(temp, predict(logit_fit), legend = false, xlabel = "Temperature", ylab = "Probability") scatter!(temp, predict(logit_fit)) ``` ![](/files/-LXNl6uIs6H86udz0yEm) The estimates of the parameters are $$\hat\alpha=15.0479, \hat\beta=-0.232163$$ and $$\hat\sigma\_\beta = 0.108137$$. Wrote the following Julia code to implement the independent MH algorithm, ```julia ## metropolis-hastings using Distributions γ = 0.57721 function ll(α::Float64, β::Float64) a = exp.(α .+ β*temp) return prod( (a ./ (1 .+ a) ).^failure .* (1 ./ (1 .+ a)).^(1 .- failure) ) end function mh_logit(T::Int, α_hat::Float64, β_hat::Float64, σ_hat::Float64) φ = Normal(β_hat, σ_hat) π = Exponential(exp(α_hat+γ)) Α = ones(T) Β = ones(T) for t = 1:T-1 α = log(rand(π)) β = rand(φ) r = ( ll(α, β) / ll(Α[t], Β[t]) ) * ( pdf(φ, β) / pdf(φ, Β[t]) ) if rand() < r Α[t+1] = α Β[t+1] = β else Α[t+1] = Α[t] Β[t+1] = Β[t] end end return Α, Β end Α, Β = mh_logit(10000, 15.04, -0.233, 0.108) p1 = plot(Α, legend = false, xlab = "Intercept") hline!([15.04]) p2 = plot(Β, legend = false, xlab = "Slope") hline!([-0.233]) plot(p1, p2, layout = (1,2)) ``` ![](/files/-LXNssFaYQCd8EN6aF3q) ## Saddlepoint tail area approximation If $$K(\tau) = \log({\mathbb E}\exp(\tau X))$$ is the [cumulant generating function](https://en.wikipedia.org/wiki/Cumulant), solving the saddlepoint equation $$K'(\tau)=x$$ yields the saddlepoint. For noncentral chi squared random variable $$X$$, the moment generating function is $$ \phi\_X(t) = \frac{\exp(2\lambda t/(1-2t))}{(1-2t)^{p/2}},, $$ where $$p$$ is the number of degrees of freedom and $$\lambda$$ is the noncentrality parameter, and its saddlepoint is $$ \hat\tau(x) = \frac{-p+2x-\sqrt{p^2+8\lambda x}}{4x},. $$ The saddlepoint can be used to approximate the tail area of a distribution. We have the approximation $$ \begin{aligned} P(\bar X>a) &= \int\_a^\infty \Big(\frac{n}{2\pi K\_X''(\hat\tau(x))}\Big)^{1/2}\exp{n\[K\_X(\hat\tau(x))-\hat\tau(x)x]}dx\\ &= \int\_{\hat\tau(a)}^{1/2} \Big(\frac{n}{2\pi}\Big)^{1/2}\[K\_X''(t)]^{1/2}\exp{n\[K\_X(t)-tK\_X'(t)]}dt\\ &\approx \frac 1m\sum\_{i=1}^m\mathbb{I}\[Z\_i>\hat \tau(a)],, \end{aligned} $$ where $$Z\_i$$ is the sample from the saddlepoint distribution. Using a Taylor series approximation, $$ \exp{n\[K\_X(t)-tK\_X'(t)]}\approx \exp\Big{-nK''\_X(0)\frac{t^2}{2}\Big},, $$ so the instrumental density can be chosen as $$N(0,\frac{1}{nK\_X''(0)})$$, where $$ K\_X''(t)=\frac{2\[p(1-2t) + 4\lambda]}{(1-2t)^3},. $$ I implemented the independent MH algorithm via the following code to produce random variables from the saddlepoint distribution. ```julia using Distributions p = 6 λ = 9 function K(t) return 2λ*t / (1-2t) - p / 2 * log(1-2t) end function D1K(t) return ( 4λ*t ) / (1-2t)^2 + ( 2λ + p ) / ( 1 - 2t ) end function D2K(t) return 2(p*(1-2t) + 4λ) / (1-2t)^3 end function logf(n, t) return n * (K(t) - t*D1K(t)) + 0.5log(D2K(t)) end function logg(n, t) return -1n * D2K(0) * t^2/2 end function mh_saddle(T::Int = 10000; n::Int = 1) Z = zeros(T) g = Normal(0, 1 / sqrt(n*D2K(0))) for t = 1:T-1 z = rand(g) logr = logf(n, z) - logf(n, Z[t]) + logg(n, Z[t]) - logg(n, z) if log(rand()) < logr Z[t+1] = z else Z[t+1] = Z[t] end end return Z end Z = mh_saddle(n = 1) function tau(x) return ( -1p + 2x - sqrt(p^2 + 8λ * x) ) / (4x) end println(sum(Z .> tau(36.225)) / 10000) println(sum(Z .> tau(40.542)) / 10000) println(sum(Z .> tau(49.333)) / 10000) ``` I can successfully reproduce the results. If $$n=1$$, | Interval | `1 - pchisq(x, 6, 9*2)` | IMH | | ------------------- | ----------------------- | ------ | | $$(36.225,\infty)$$ | 0.1000076 | 0.1037 | | $$(40.542,\infty)$$ | 0.05000061 | 0.0516 | | $$(49.333,\infty)$$ | 0.01000057 | 0.0114 | For $$n=100$$, note that if $$X\_i\sim \chi^2\_p(\lambda)$$, then $$n\bar X=\sum X\_i\sim \chi^2\_{np}(n\lambda)$$, then we can use the following R code to figure out the cutpoints. ```r qchisq(0.90, 600, 1800)/100 qchisq(0.95, 600, 1800)/100 qchisq(0.99, 600, 1800)/100 ``` Then use these cutpoints to estimate the probability by using samples produced from independent MH algorithm. | Interval | `1 - pchisq(x*100, 6*100, 9*2*100)` | IMH | | --------------------- | ----------------------------------- | ------ | | $$(25.18054,\infty)$$ | 0.10 | 0.1045 | | $$(25.52361,\infty)$$ | 0.05 | 0.0516 | | $$(26.17395,\infty)$$ | 0.01 | 0.0093 | --- # Agent Instructions: Querying This Documentation If you need additional information that is not directly available in this page, you can query the documentation dynamically by asking a question. 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