We added idNeuralStateSpace object that support both continuous and discrete time model. Maybe this could be useful. It was created to simplify code you have to write, so it would not allow you to write your own training loop though.
Equivalent of Neural ODE for discrete time state space models
7 visualizaciones (últimos 30 días)
Mostrar comentarios más antiguos
M.
el 25 de En. de 2023
Here is the example on how to train neural ODE to identify dynamical system :
https://mathworks.com/help/deeplearning/ug/dynamical-system-modeling-using-neural-ode.html
This example talks about continuous time models and I was wondering if there was any equivalent tutorial related to discrete time models ?
0 comentarios
Respuesta aceptada
Arkadiy Turevskiy
el 31 de En. de 2023
1 comentario
Ben
el 2 de Feb. de 2023
Hi M.
I'm not sure if this is possible with the shallow network functions but it can be done with the dlnetwork and custom training loops since these we allow you to write your own model function that re-uses the same network on 2 different inputs. Here's some example code with dummy data - in practice you may need to tweak the training and network hyperparameters to get optimal performance.
% share a neural net across multiple calls
% create some fake data
% predict x(t+1) = F(x(1,t),u(1,t)) + F(x(2,t),u(2,t)) for some unknown F
numSteps = 100;
t = linspace(0,2*pi,numSteps);
F = @(x,u) sqrt(x+u+1);
x = [0;1];
u = [cos(t);sin(t)];
for i = 2:numSteps
x(:,i) = F(x(1,i-1),u(1,i-1)) + F(x(2,i-1),u(2,i-1));
end
% create a network to model F
% it needs to have two inputs, for x and u.
hiddenSize = 5000;
inputSize = 1;
outputSize = 2;
layers = [
featureInputLayer(inputSize,Name="x")
concatenationLayer(1,2,Name="concat");
fullyConnectedLayer(hiddenSize)
reluLayer
fullyConnectedLayer(outputSize)];
net = dlnetwork(layers,Initialize=false);
net = addLayers(net,featureInputLayer(1,Name="u"));
net = connectLayers(net,"u","concat/in2");
net = initialize(net);
% train with custom training loop
numEpochs = 1000;
vel = [];
x = dlarray(x,"CB");
u = dlarray(u,"CB");
learnRate = 0.1;
for epoch = 1:numEpochs
[loss,gradient] = dlfeval(@modelLoss,x,u,net);
lossValue = extractdata(loss);
fprintf("Epoch: %d, Loss %.4f\n", epoch, lossValue);
[net,vel] = sgdmupdate(net,gradient,vel,learnRate);
end
function [loss,gradient] = modelLoss(x,u,net)
% predict x(:,2:end) from x(:,1:end-1) and u(:,1:end-1)
xtarget = x(:,2:end);
xpred = model(x(:,1:end-1),u(:,1:end-1),net);
loss = mse(xtarget,xpred);
gradient = dlgradient(loss,net.Learnables);
end
function xpred = model(x,u,net)
% model xpred = x(t+1) = f(x(1,t),u(1,t)) + f(x(2,t),u(2,t)) where f is a neural net.
xpred = forward(net,x(1,:),u(1,:)) + forward(net,x(2,:),u(2,:));
end
Hope that helps.
Más respuestas (0)
Ver también
Categorías
Más información sobre Custom Training Loops en Help Center y File Exchange.
Community Treasure Hunt
Find the treasures in MATLAB Central and discover how the community can help you!
Start Hunting!
Translated by 
También puede seleccionar uno de estos países/idiomas:
América
- América Latina (Español)
- Canada (English)
- United States (English)
Europa
- Belgium (English)
- Denmark (English)
- Deutschland (Deutsch)
- España (Español)
- Finland (English)
- France (Français)
- Ireland (English)
- Italia (Italiano)
- Luxembourg (English)
- Netherlands (English)
- Norway (English)
- Österreich (Deutsch)
- Portugal (English)
- Sweden (English)
- Switzerland
- United Kingdom(English)
Asia-Pacífico
- Australia (English)
- India (English)
- New Zealand (English)
- 中国
- 日本Japanese (日本語)
- 한국Korean (한국어)