## Hot answers tagged montecarlo

7

The algorithm for your first version should look more like this:
from __future__ import division, print_function
import sys
if sys.version_info.major < 3:
range = xrange
import random
incircle = 0
n = 100000
for n in range(n):
x = random.random()
y = random.random()
if (x*x + y*y <= 1):
incircle += 1
pi = (incircle / n) * ...

5

Ok, first let's start with simple transformation, log(x) -> x, making integral
I = S 2/(1+x^2) dx, x in [0...infinity]
where S is integration sign.
So function 1/(1+x^2) is falling monotonically and reasonable fast. We need some reasonable PDF to sample points in [0...infinity] interval, such that most of the region where original function is ...

3

Using mean() inside your function interferes with vectorization. You can wrap your function in Vectorize() to fix it. For example
f <- Vectorize(function(x) {y=runif(10^6,0,x); return(x*mean((1/(1+y^2))))})

2

I guess the mathematical answer would be:
y = p(x | M) = \sum_i p(x | N_i) * w_i
where p(x | M) is the probability of x being sampled form the mixture M, which is translated to the weighted sum of the probability of x being sampled from each of the gaussians N_i weighted by the prior probability of sampling from the normal N_i (w_i, a weight obtained ...

2

For the first one, your calculation should be
pi = incircle/1000000*4 # 3.145376..
This is the number of points that landed inside of the circle over the number of total points (approximately 0.785671 on my run).
With a radius of 1 (random.uniform(-1,1)), the total area is 4, so if you multiple 4 by the ratio of points that landed inside of the circle, ...

1

Your problem obviously is an exploration problem, and the problem is that with Upper Confidence Bound (UCB), the exploration cannot be tuned directly. This can be solved by adding an exploration constant.
The Upper Confidence Bound (UCB) is calculated as follows:
with V being the value function (expected score) which you are trying to optimize, s the ...

1

Not a mathematical answer but Matlab provides the pdf evaluations using the 'pdf' method.
y = pdf(obj,X)
where obj is the gmdistribution object.

Only top voted, non community-wiki answers of a minimum length are eligible