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ildp.m @ 883

Revision 755, 10.3 kB (checked in by vahalam, 15 years ago)

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1	function ildp
2
3	tic
4	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
5	%pocatecni konstanty
6
7	% [b=1, yr=1] - to jsme zkouseli spolu sigma = 0.1; rho = 0.5;
8	% [b=-1, yr=1] sigma = 0.1; rho = 0.5; !aprior
9	% [b=10, yr=5] sigma = 0.5; rho = 2.0;
10	% [b=0.6, yr=10] sigma = 0.1; rho = 1.0;
11
12	Iterace = 10; %iterace
13	K = 5; %casy
14	N = 100; %vzorky
15
16	sigma = 0.1;
17	Sigmas = [[sigma^2 0 0]; [0 0 0]; [0 0 0]];
18
19	h = 0;
20	hdx = [0; 0; 0];
21	hdxdx = [[0 0 0]; [0 0 0]; [0 0 0]];
22
23	Rk = 1*ones(1, K);
24	x0 = [0; 1; 1];
25
26	%velikost okoli pro lokalni metodu
27	rho = 0.5;
28	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
29	%globalni promenne
30
31	Kpi = ones(4, K);
32	Kpi(4, :) = zeros(1, K);
33	% Kpi(3, :) = zeros(1, K);
34
35	Wv = zeros(9, K);
36
37	Xkn = zeros(3, K, N);
38	Xstripe = zeros(3, K);
39
40	gka = 0;
41	gnu = 0;
42
43	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
44	%iteracni smycka
45
46	for i = 1:Iterace,
47	%generovani stavu
48	for n = 1:N,
49	Xkn(:, 1, n) = x0 + [sigma*randn(); 0; 0];
50	for k = 1:K-1,
51	Uk = uPi(k, Xkn(:, k, n));
52	Kk = UkXkn(3, k, n)/(Uk^2Xkn(3, k, n) + sigma^2);
53	Xkn(1, k+1, n) = Xkn(1, k, n) + Xkn(2, k, n)Uk + sigmarandn();
54	Xkn(2, k+1, n) = Xkn(2, k, n) + Kk(Xkn(1, k+1, n) - Xkn(1, k, n) - Xkn(2, k, n)Uk);
55	Xkn(3, k+1, n) = (1 - KkUk)Xkn(3, k, n);
56	end
57	end
58	Xstripe = mean(Xkn, 3);
59
60	for k = K-1:-1:1,
61	gka = k;
62	% 1]
63	for n = 1:N,
64	%krive okoli
65	Xkn(1, k, n) = Xstripe(1, k) + rho*randn();
66	Xkn(2, k, n) = Xstripe(2, k) + rho*randn();
67	Xkn(3, k, n) = Xstripe(3, k)exp(rhorandn());
68	end
69	% 2]
70	for n = 1:N,
71	gnu = n;
72	[Uopt(n), Hmin(n)] = fminunc(@Hamilt, uPi(k, Xkn(:, k, n)), optimset('GradObj','on','Display','notify'));
73	end
74	% 3]
75	for n = 1:N,
76	Vn(n) = Hmin(n) + Vtilde(k+1, Xkn(:, k, n));
77	end
78	% 4]
79	Epsilon = zeros(3, N);
80	for n = 1:N,
81	Epsilon(1, n) = Xkn(1, k, n) - Xstripe(1, k);
82	Epsilon(2, n) = Xkn(2, k, n) - Xstripe(2, k);
83	Epsilon(3, n) = Xkn(3, k, n)/Xstripe(3, k);
84	end
85	mFi = matrixFi(Epsilon);
86	FiFiTInvFi = (mFi*mFi')\mFi;
87	Wv(:,k) = FiFiTInvFi * Vn';
88	for n = 1:N,
89	yt(n) = Xkn(1, k, n);
90	bt(n) = Xkn(2, k, n);
91	pt(n) = Xkn(3, k, n);
92	end
93	mPsi = [yt',...
94	bt'.*Uopt',...
95	pt'.*Uopt',...
96	Uopt'];
97	PsiPsiTInvPsi = (mPsi'*mPsi)\mPsi';
98	Kpi(:,k) = PsiPsiTInvPsi * (Rk(k)*ones(N,1));
99	end
100	end
101	%%%%%%%%%%%
102	toc
103
104	Kpi
105
106	for n = 1:N,
107	Xkn(:, 1, n) = x0 + [sigma*randn(); 0; 0];
108	for k = 1:K-1,
109	Uk = uPi(k, Xkn(:, k, n));
110	UU(k,n) = Uk;
111	Kk = UkXkn(3, k, n)/(Uk^2Xkn(3, k, n) + sigma^2);
112	Xkn(1, k+1, n) = Xkn(1, k, n) + Xkn(2, k, n)Uk + sigmarandn();
113	Xkn(2, k+1, n) = Xkn(2, k, n) + Kk(Xkn(1, k+1, n) - Xkn(1, k, n) - Xkn(2, k, n)Uk);
114	Xkn(3, k+1, n) = (1 - KkUk)Xkn(3, k, n);
115	end
116	hold all
117	subplot(4,1,1);
118	plot(1:K,Xkn(1,:,n))
119	hold all
120	subplot(4,1,2);
121	plot(1:K,Xkn(2,:,n))
122	hold all
123	subplot(4,1,3);
124	plot(1:K,Xkn(3,:,n))
125	hold all
126	subplot(4,1,4);
127	plot(1:K-1,UU(:,n))
128
129	end
130	title('iLDP')
131	figure
132	for n = 1:N,
133	Xkn(:, 1, n) = x0 + [sigma*randn(); 0; 0];
134	for k = 1:K-1,
135	Uk = (Rk(k) - Xkn(1, k, n))/(Xkn(2, k, n) + Xkn(3, k, n));
136	UU(k,n) = Uk;
137	Kk = UkXkn(3, k, n)/(Uk^2Xkn(3, k, n) + sigma^2);
138	Xkn(1, k+1, n) = Xkn(1, k, n) + Xkn(2, k, n)Uk + sigmarandn();
139	Xkn(2, k+1, n) = Xkn(2, k, n) + Kk(Xkn(1, k+1, n) - Xkn(1, k, n) - Xkn(2, k, n)Uk);
140	Xkn(3, k+1, n) = (1 - KkUk)Xkn(3, k, n);
141	end
142	hold all
143	subplot(4,1,1);
144	plot(1:K,Xkn(1,:,n))
145	hold all
146	subplot(4,1,2);
147	plot(1:K,Xkn(2,:,n))
148	hold all
149	subplot(4,1,3);
150	plot(1:K,Xkn(3,:,n))
151	hold all
152	subplot(4,1,4);
153	plot(1:K-1,UU(:,n))
154
155	end
156	title('CE')
157
158	for vzorek = 1:100,
159	loss(vzorek) = 0;
160	bb = randn() + x0(2);
161	yy(1) = x0(1);
162	for k=1:K-1,
163	yy(k+1)=yy(k)+bb*uPi(k,[yy(k); bb; 0]);
164	loss(vzorek) = loss(vzorek) + (yy(k+1) - Rk(k+1))^2;
165	end
166	end
167	figure
168	hist(log(loss))
169
170	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
171	%pomocne funkce
172
173	function [val_uPi] = uPi(k_uPi, x_uPi)
174	val_uPi = (Rk(k_uPi) - Kpi(1, k_uPi)x_uPi(1))/(Kpi(2, k_uPi)x_uPi(2) + Kpi(3, k_uPi)*x_uPi(3) + Kpi(4, k_uPi));
175
176	end
177
178	function [val_ham, val_grad] = Hamilt(u_ham)
179	% Vtddx = Vtilde_dx(gka+1, Xkn(:, gka, gnu));
180	val_ham = (Xkn(1, gka, gnu) + Xkn(2, gka, gnu)u_ham - Rk(gka+1))^2 + Xkn(3, gka, gnu)u_ham^2 ... + sigma^2 ... %ztrata l
181	+ [Xkn(2, gka, gnu)*u_ham; ...
182	Xkn(3, gka, gnu)u_ham(Xkn(1, gka+1, gnu) - Xkn(1, gka, gnu) - Xkn(2, gka, gnu)u_ham)/(Xkn(3, gka, gnu)u_ham^2 + sigma^2); ...
183	-Xkn(3, gka, gnu)^2u_ham^2/(Xkn(3, gka, gnu)u_ham^2 + sigma^2)]' ... %fce f
184	*Vtilde_dx(gka+1, Xkn(:, gka, gnu)) ...
185	+ Wv(5, gka+1)sigma;%+ Wv(4, gka+1)sigma;
186
187	val_grad = 2(Xkn(1, gka, gnu) + Xkn(2, gka, gnu)u_ham - Rk(gka+1))Xkn(2, gka, gnu) + 2Xkn(3, gka, gnu)*u_ham ... %ztrata du
188	+ [Xkn(2, gka, gnu);...
189	(2u_ham^2Xkn(3, gka, gnu)^2(Xkn(1, gka, gnu) - Xkn(1, gka+1, gnu) + u_hamXkn(2, gka, gnu)))/(sigma^2 + u_ham^2Xkn(3, gka, gnu))^2 - (u_hamXkn(2, gka, gnu)Xkn(3, gka, gnu))/(sigma^2 + u_ham^2Xkn(3, gka, gnu)) - (Xkn(3, gka, gnu)(Xkn(1, gka, gnu) - Xkn(1, gka+1, gnu) + u_hamXkn(2, gka, gnu)))/(sigma^2 + u_ham^2*Xkn(3, gka, gnu));...
190	(2u_ham^3Xkn(3, gka, gnu)^3)/(sigma^2 + u_ham^2Xkn(3, gka, gnu))^2 - (2u_hamXkn(3, gka, gnu)^2)/(sigma^2 + u_ham^2Xkn(3, gka, gnu))]' ... %fce f du
191	* Vtilde_dx(gka+1, Xkn(:, gka, gnu)); %derivace Bellman fce
192	end
193
194	function [val_Vt] = Vtilde(k_Vt, x_Vt)
195	if(k_Vt == K)
196	val_Vt = h;
197	else
198	Epsl = zeros(3, 1);
199	Epsl(1) = x_Vt(1) - Xstripe(1, k_Vt);
200	Epsl(2) = x_Vt(2) - Xstripe(2, k_Vt);
201	Epsl(3) = x_Vt(3)/Xstripe(3, k_Vt);
202
203	val_Vt = vectFi(Epsl)' * Wv(:,k_Vt);
204	end
205	end
206
207	function [val_Vt] = Vtilde_dx(k_Vt, x_Vt)
208	if(k_Vt == K)
209	val_Vt = hdx;
210	else
211	Epsl = zeros(3, 1);
212	Epsl(1) = x_Vt(1) - Xstripe(1, k_Vt);
213	Epsl(2) = x_Vt(2) - Xstripe(2, k_Vt);
214	Epsl(3) = x_Vt(3)/Xstripe(3, k_Vt);
215
216	val_Vt = difFi(Epsl)' * Wv(:,k_Vt);
217	end
218	end
219
220	function [val_Fi] = vectFi(x_Fi)
221	val_Fi = [ ...
222	1; ...
223	x_Fi(1); ...
224	x_Fi(2); ...
225	log(x_Fi(3)); ...
226	x_Fi(1)^2; ...
227	x_Fi(1)*x_Fi(2); ...
228	x_Fi(1)*log(x_Fi(3)); ...
229	x_Fi(2)^2; ...
230	x_Fi(2)*log(x_Fi(3)); ...
231	% 2*ln(x_Fi(3)); ...
232	];
233	end
234
235	function [val_Fi] = matrixFi(x_Fi)
236	val_Fi = [ ...
237	ones(1, N); ...
238	x_Fi(1, :); ...
239	x_Fi(2, :); ...
240	log(x_Fi(3, :)); ...
241	x_Fi(1, :).^2; ...
242	x_Fi(1, :).*x_Fi(2, :); ...
243	x_Fi(1, :).*log(x_Fi(3, :)); ...
244	x_Fi(2, :).^2; ...
245	x_Fi(2, :).*log(x_Fi(3, :)); ...
246	];
247
248	end
249
250	function [val_Fi] = difFi(x_Fi)
251	val_Fi = [ ...
252	0 0 0; ...
253	1 0 0; ...
254	0 1 0; ...
255	0 0 1/(x_Fi(3)); ...
256	2*x_Fi(1) 0 0; ...
257	x_Fi(2) x_Fi(1) 0; ...
258	log(x_Fi(3)) 0 x_Fi(1)/(x_Fi(3)); ...
259	0 2*x_Fi(2) 0; ...
260	0 log(x_Fi(3)) x_Fi(2)/(x_Fi(3)); ...
261	];
262	end
263	end

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