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I have a question that may be trivial but it's not described anywhere i've looked. I'm studying neural networks and everywhere i look there's some theory and some trivial example with some 0s and 1s as an input. I'm wondering: do i have to put only one value as an input value for one neuron, or can it be a vector of, let's say, 3 values (RGB colour for example)?

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5 Answers

When dealing with multi-dimensional data, I believe a two layer neural network is said to give better result.

In your case:

R[0..1] => (N1)----\
                    \
G[0..1] => (N2)-----(N4) => Result[0..1]
                    /
B[0..1] => (N3)----/

As you can see, the N4 neurone can handle 3 entries.

The [0..1] interval is a convention but a good one imo. That way, you can easily code a set of generic neuron classes that can take an arbitrary number of entries (I had template C++ classes with the number of entries as template parameter personally). So you code the logic of your neurons once, then you toy with the structure of the network and/or combinations of functions within your neurons.

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but that's not a 3-dimentional data.... it's one value for one neuron –  agnieszka Mar 16 '09 at 23:55
    
the problem is i have set of pixels of an image, i have some (3?) subsequent images of a one view that give me some (3?) different colours of a one pixel. each colour consists of 3 values. the question is - to be continued –  agnieszka Mar 16 '09 at 23:57
    
the question is should i desing one input neuron for each r and g and b for every pixel for every image or can i put a colour (r,g,b value) as an input for one neuron, or maybe 3 subsequent colours? –  agnieszka Mar 16 '09 at 23:58
    
The thing is you have a lot of options here. What is the problem exactly? If it's local to each pixel (ie, the solution only depends on the three consecutive colors of the same pixel) then you only need one neural network into which you'll enter you data (...) –  Julian Aubourg Mar 17 '09 at 0:21
    
(...) pixel by pixel. Now, how a neural network should be configured? There's no real answer to that. Should you have 3 subnetworks like the one I have into my post than cumulate their result into another neuron? Should you have 9 entry neurons and one cumulator in the end? (...) –  Julian Aubourg Mar 17 '09 at 0:22
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The above answers are technically correct, but don't explain the simple truth: there is never a situation where you'd need to give a vector of numbers to a single neuron.

From a practical standpoint this is because (as one of the earlier solutions has shown) you can just have a neuron for each number in a vector and then have all of those be the input to a single neuron. This should get you your desired behavior after training, as the second layer neuron can effectively make use of the entire vector.

From a mathematical standpoint, there is a fundamental theorem of coding theory that states that any vector of numbers can be represented as a single number. Thus, if you really don't want an extra layer of neurons, you could simply encode the RGB values into a single number and input that to the neuron. Though, this coding function would probably make most learning problems more difficult, so I doubt this solution would be worth it in most cases.

To summarize: artificial neural networks are used without giving a vector to an input unit, but lose no computational power because of this.

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Normally a single neuron takes as its input multiple real numbers and outputs a real number, which typically is calculated as applying the sigmoid function to the sum of the real numbers (scaled, and then plus or minus a constant offset).

If you want to put in, say, two RGB vectors (2 x 3 reals), you need to decide how you want to combine the values. If you add all the elements together and apply the sigmoid function, it is equivalent to getting in six reals "flat". On the other hand, if you process the R elements, then the G elements, and the B elements, all individually (e.g. sum or subtract the pairs), you have in practice three independent neurons.

So in short, no, a single neuron does not take in vector values.

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so in a situation you described you have 3 input neurons, each one getting a value that consists of three values, for example three Rs? –  agnieszka Mar 17 '09 at 0:18
    
Ah, there where actually only two R's in the example above, but yes, one way would be to dedicate one neuron per one element. –  Antti Huima Mar 17 '09 at 0:22
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It can be whatever you want, as long as you write your inner function accordingly.

The examples you mention use [0;1] as their domain, but you can use R, R², or whatever you want, as long as the function you use in your neurons is defined on this domain.

In your case, you can define your functions on R3 to allow for RGB values to be handled

A trivial example : use (x1, y1, z1),(x2,y2,z2)->(ax1+x2,by1+y2,cz1+z2) as your function to transform two colors into one, a b and c being your learning coefs, which you will determine during the learning phase.

Very detailed information (including the answer to your question) is available on Wikipedia.

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but if one dataset stays in a relation with another dataset they should be provided to different neurons, shouldn't they? or may it be a one vector's input? –  agnieszka Mar 16 '09 at 23:36
    
yes, it can be a one vector input ; R3 means a 3-members vector (well, trivially speaking) –  Brann Mar 16 '09 at 23:37
    
well yeah i get that :D i mean if you have 3 colours of a one pixel in 3 subsequent images and you know that differences between these colours influence the result should you have 3 neurons for these 3 colors or one neuron for an input containing these 3 colours? or do i choose? –  agnieszka Mar 16 '09 at 23:41
    
I guess I would use an array of neurons (1 per pixel), with each neurons getting three RGB vectors (one per same coordinate pixel of each image) as input values. –  Brann Mar 16 '09 at 23:44
    
thanks that was helpful! the last question - does it mean that i HAVE to have a function that changes my R^n value to a R value for an input neuron? –  agnieszka Mar 16 '09 at 23:46
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Use light wavelength normalized to visible spectrum as the input.

There are some approximate equations on the net. Search for RGB to wavelength conversion or use HSL color model and extract Hue component and possibly use Saturation and Lightness as well. Well...

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