M
M
Monte-Carlo
Home
ESL-CN
TechNotes
Blog
Search…
Introduction
AIS
Generate R.V.
Gibbs
Markov Chain
MC Approximation
MC Integration
Rao-Blackwellization
MC Optimization
MCMC
Metropolis-Hastings
PBMCMC
RJMCMC
Diagnosing Convergence
SMCTC
Tempering
Misc
References
Powered By
GitBook
MC Integration
Classical Monte Carlo Integration
Robert and Casella (2013)
introduces the classical Monte Carlo integration:
Toy Example
为了计算积分
我们通常采用MC模拟:
1.
计算区域的volume:
2.
近似:
根据大数律有
并且由中心极限定理有
其中
另外,注意到
I
=
∫
D
g
(
x
)
d
x
=
∫
D
V
g
(
x
)
1
V
d
x
=
E
f
[
V
g
(
x
)
]
,
I = \int_Dg(\mathbf x)d\mathbf x = \int_D Vg(\mathbf x)\frac 1V d\mathbf x = {\mathbb E}_f[Vg(\mathbf x)],
I
=
∫
D
g
(
x
)
d
x
=
∫
D
V
g
(
x
)
V
1
d
x
=
E
f
[
V
g
(
x
)]
,
则可以直接利用上一节的结论。
## 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)
.
The following Julia program can be used to do polar simulation.
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
)
Previous
MC Approximation
Next
Rao-Blackwellization
Last modified
3yr ago
Copy link
Outline
Classical Monte Carlo Integration
Toy Example
Polar Simulation