Neural ODE for dynamic systems with input signals

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Bowei Li on 24 Jan 2022

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Edited: Sergio on 29 Apr 2025

Accepted Answer: Ben

Hi! Community!

Mathworks provided a nice example here for modeling dynamic systems through neural ODE.

Is it possible to consider input signals in training? That is, to define the differential equation to be:

where

is the input signal.

However, dlode45 will not allow the ODE function to be with more than three inputs.

So is there any other possible approach to incorporate the input signal?

Thanks a lot!

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Answer 1

Ben on 25 Jan 2022

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Hi Bowei,

You should be able to create a new ODE function that has only three inputs as required. Let me show a few cases.

Case 1 -

In this case you can define

. Assuming you have f as a function handle you can define g in code with:

g = @(t,x,theta) f(t,x,theta,e(t))

Then solve using g in dlode45.

Case 2 -

This is a special case of case 1:

g = @(t,x,theta) f(t,x,theta) + e(t)

Call dlode45 with g.

Case 3 -

for

In this case you have an extra hyperparameter i which you just have to select a specific value for. For example let

and

. You could write this in code as:

e = @(t,i) cos(i*t);

f = @(t,x,A,i) A*x + e(t,i);

x0 = dlarray(randn());

tspan = [0,1];

A = dlarray(randn());

i = 3;

x = dlode45(@(t,x,A) f(t,x,A,i), tspan, x0, A, DataFormat="CB");

Note that in this case you can loop over the values you want for i.

Hope that helps,

Ben

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Ben on 15 Jan 2024

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Hi @Shubham Baisthakur

Firstly neuralODELayer is only available from R2023b. If R2023a you could use a custom layer using dlode45.

To use neuralODELayer with an external input signal, you will need to be able to implement that external input signal in the dlnetwork that is passed to neuralODELayer. You create layer = neuralODELayer(odenet, tspan), if odenet has 1 input then this corresponds to integrating the ODE

. If odenet has 2 inputs then it is

. So if you're modelling an ODE of the form

then you need implement

withing the odenet.

As an example, here's how you could create

.

x0 = dlarray(1,"CB");
t0 = dlarray(0,"CB");
sinLayer = functionLayer(@sin, Acceleratable=true);
hiddenSize = 10;
odenet = [
    sinLayer
    concatenationLayer(1,2)
    fullyConnectedLayer(hiddenSize)
    tanhLayer
    fullyConnectedLayer(1)];
odenet = dlnetwork(odenet,t0,x0);
tspan = [0,0.1];
odeLayer = neuralODELayer(odenet,tspan);
odeLayer = 
  NeuralODELayer with properties:

                 Name: ''
         TimeInterval: [0 0.1000]
         GradientMode: 'direct'
    RelativeTolerance: 1.0000e-03
    AbsoluteTolerance: 1.0000e-06

   Learnable Parameters
              Network: [1×1 dlnetwork]

   State Parameters
    No properties.

Use properties method to see a list of all properties.

Here the odenet-s first input is t which becomes

via the sinLayer. Then I concatenate

with the second input to odenet, x to create

, and pass that through standard neural network layers.

A more difficult case is that you don't know a functional form for

, but only have samples

. In this case, instead of sinLayer = functionLayer(@sin) you should use a layer that interpolates

from the samples

. One way to do this is with interp1. Here's some code demonstrating that, I'll use

again just to demonstrate.

% create toy data
ti = dlarray(linspace(0,1,10));
ui = sin(ti); % in practice you aren't aware of the functional form of u(t).
interpLayer = functionLayer(@(t) dlarray(interp1(ti,ui,t),"CB"), Acceleratable=true);

Next you use interpLayer just like sinLayer above. Part of what this does is store the sample data ti, ui on the interpLayer (actually on the function_handle on that layer). A more flexible approach would be to implement a custom layer to perform this interpolation.

If you have multiple different external signals

corresponding to different observations/batch elements, you may need a more intricate approach, since you will have to align the

with the batch element inputs to odenet.

Sergio on 11 Dec 2024

Edited: Sergio on 11 Dec 2024

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Hello Ben,

Thank you for providing this useful explanation however there are some aspects in the application of NeuralODELayer I do not completely understand and I would appreciate your help with them.

The examples illustrated above created a odeLayer which must be included within a different neural network in order to be applied. For instance:

Layers =[
    featureInputLayer(2,'Name','Input')
    neuralODELayer(odeLayer, timesteps, 'GradientMode', 'adjoint', 'Name', 'neuralODE')
    ];
net = dlnetwork(Layers);

And to train the model we need:

net = trainnet(net_input, targets, net, "huber", options);

Here is where my doubt lies, to train the model net_input and targets must have the same dimensions. What would happen if u(t) and targets match in their length and time steps but we only have a single value of x0 (which is the initialization of X)?

Additionally, if there is a way to reproduce the example provided by Mathworks with the application of neuralODELayer? In the aforementioned example the dlode45 function is applied and their inputs are: timesteps, initial value of y (y0) and theta (weights and biases of the NN). If I intend to use neuralODELayer and trainnet the dimensions of the inputs and targets do not match because y0 is obteined from the targets.

Ben on 11 Dec 2024

Edited: Ben on 11 Dec 2024

Hi @Sergio,

On the second question regarding the example, neuralODELayer can be used here as follows:

% https://uk.mathworks.com/help/deeplearning/ug/dynamical-system-modeling-using-neural-ode.html

% using neuralODELayer

% Generate training data

x0 = [2; 0];

A = [-0.1 -1; 1 -0.1];

trueModel = @(t,y) A*y;

numTimeSteps = 2000;

T = 15;

odeOptions = odeset(RelTol=1.e-7);

t = linspace(0, T, numTimeSteps);

[~, xTrain] = ode45(trueModel, t, x0, odeOptions);

xTrain = xTrain';

% Rearrange the single solution [x(1),x(2),...,x(end)] into subsequences

% x(t) and [x(t+1), ..., x(t+40)].

neuralOdeTimesteps = 40;

dt = t(2);

timesteps = (0:neuralOdeTimesteps)*dt;

input = xTrain(:,1:end-neuralOdeTimesteps);

numObs = numTimeSteps - neuralOdeTimesteps;

targets = cell(numObs, 1);

for i = 1:numObs

targets{i} = xTrain(:,i + (1:neuralOdeTimesteps));

end

% Design neural ODE.

stateSize = size(xTrain,1);

hiddenSize = 20;

odeNet = [

fullyConnectedLayer(hiddenSize)

tanhLayer

fullyConnectedLayer(stateSize)];

odeNet = dlnetwork(odeNet,Initialize=false);

odeLayer = neuralODELayer(odeNet,timesteps,GradientMode="adjoint");

net = dlnetwork([featureInputLayer(stateSize); odeLayer]);

% Train neural ODE.

opts = trainingOptions("adam", ...

Plots="training-progress", ...

ExecutionEnvironment="cpu", ...

InputDataFormats="CB",...

TargetDataFormats="CTB");

trainednet = trainnet(input,targets,net,"l2loss",opts);

% Use neural ODE to predict on a longer time interval.

% This requires extracting the layer, setting the new time interval, and

% calling replaceLayer to put the layer back into the network with the new

% time interval.

% Alternatively you can extract odeNet = trainednet.Layers(2).Network and use

% dlode45(odeNet, t, x0)

layer = trainednet.Layers(2);

layer.TimeInterval = t;

inferencenet = replaceLayer(trainednet,layer.Name,layer);

inferencenet = initialize(inferencenet);

x0Pred1 = sqrt([2,2]);

xPred1 = predict(inferencenet,x0Pred1);

plot(xPred1(:,1),xPred1(:,2))

Regarding trainnet - the inputs and targets don't have to have the same dimensions. A neuralODELayer(net, ts) will take an initial condition

as input, corresponding to the state at time ts(1), and output the solution as a sequence (with T dimension) at times ts(2:end).

Hope that helps.

Sergio on 11 Dec 2024

Thanks @Ben! It helps :)

Sergio on 29 Apr 2025

Edited: Sergio on 29 Apr 2025

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Hi again @Ben,

After reading your suggestions regarding the application of neuralODELayer with external input signals I created a custom layer to work with multiple input signals. The approach I followed works when the inputs signals are not splited into minibatches manually like the variable targets in the example you provided

for i = 1:numObs
    targets{i} = xTrain(:,i + (1:neuralOdeTimesteps));
end

If I split the input signals in a similar fashion, the script does not run. I posted a new question here providing more details.

The question I have is if splitting the targets and the input signals manually (like in your example) should do the same as setting the minibatches within trainingOptions before using the trainnet function to train the model.

I appreciate your help in advance

Sergio

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Answer 2

David Willingham on 24 Jan 2022

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Hi Bowei,

Thanks for the feedback on our neural ode example! For your request, can you elloborate on what type of signal e(t) might be and what use cases you're looking to apply neural ode's to?

David

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Bowei Li on 25 Jan 2022

Edited: Bowei Li on 25 Jan 2022

Thanks David!

I was thinking about training neural ode for predicting states of dynamic systems given some arbitrary input signals, such as:

where

is the system state vector, a function of time t;

the input signal is also a function of time t.

For example,

can be like

or

or a random process

.

The example here corresponding to the case of

and training a neural ode for a set of initial conditions.

Is it possible to train a neural ode for a fixed initial condition, but for a set of input signals

.

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Neural ODE for dynamic systems with input signals

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