Dynamical Neuroscience: Wiki Article Entry - Input Needed

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In summary, the article seems to be oriented toward ANN-based AI, and does not have much relevance to dynamical neuroscience. I recommend that it be merged with another article on dynamical systems and completely rewritten.
  • #1
Pythagorean
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I've just made a wiki article entry, and would be interested on input from professionals.

http://en.wikipedia.org/wiki/Dynamical_Neuroscience [Broken]

thanks!
 
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  • #2
I am not going to critique anything specific but make this note: The moment you say 'dynamical' you mean a flow/difference mathematical mapping representation of a system. All comments about AI and the ANN neuron are absolutely irrelevant to 'dynamical neuroscience'. You don't study only 'learning and memory' type problems in 'dynamical neuroscience', you study the biological physics, chemical kinetics, electrochemistry, transport phenomena and emergent behavior of the systems as well.

So the article seems more suited to 'some differences between ANN and dynamical neuroscience'. I am going to recommend the article to be merged with some other article on dynamical systems and completely rewritten. Its got way too many facts muddled up and tries to make facts of personal conjectures.

Edit: The article is poorly written, ideas get thrown around everywhere. No structure and no clarity. Consider heavy revisions, and focus on improving single sections.
 
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  • #3
sshzp4 said:
I am not going to critique anything specific but make this note: The moment you say 'dynamical' you mean a flow/difference mathematical mapping representation of a system. All comments about AI and the ANN neuron are absolutely irrelevant to 'dynamical neuroscience'. You don't study only 'learning and memory' type problems in 'dynamical neuroscience', you study the biological physics, chemical kinetics, electrochemistry, transport phenomena and emergent behavior of the systems as well.

I disagree with that. The moment I hear "dynamical" I think evolution equations and when it's coupled with neuroscience, I think "massively fed-back non-linear evolution equations". I think both AI and neural networks are extremely relevant to the idea of approaching the brain from the perspective of it's dynamic properties. Neural networks are non-linear dynamical systems and artificial intelligence, I am utterly convinced can emerge from such systems. Personally, my view is that problems in "dynamical neuroscience" are mathematical problems: how do we understand the non-linear dynamical properties of very complicated coupled systems of non-linear equations that we believe model the dynamics of neural assemblies.

I am happy to see more effort to approach the workings of the brain in terms of it's purely intrinsic dynamic properties and am optimistic that will lead us to a more complete understanding of mind, consciousness, and self-awareness.
 
  • #4
Jack -- "I am happy to see more effort to approach the workings of the brain in terms of it's purely intrinsic dynamic properties and am optimistic that will lead us to a more complete understanding of mind, consciousness, and self-awareness."

You put too much confidence in NLD and ANeurons, my friend :)

Well my comment should be examined under the light of the wiki-author putting too much emphasis on a comparison between ANN based AI and dynamical neuroscience. It seems like a slap on the face of scientists who, say, model the neurochemistry dynamics and should be viewed as being dynamical neuroscientists as well. Without the experimentalists and without the biochemists working in the field, you wouldn't have physics to model and would be left with blind conjectures. So in a nutshell, my statement is "don't draw boundaries based on personal experience/opinions in the description of a field".

My observation of irrelevance comes from constructed implications in the article such as "Even in this day and age of lightning communication, Dynamical Neuroscience didn't even receive it's own wiki article until 2010". For a good reason, obviously. Since the field is nascent and borrows formalism better addressed under ANN mathematics, or dynamics and wikipedia is not the forum to engage in opinionated descriptions.

(You might like Seung and Lee's work at MIT on NMF algorithms. They show the statistical perspective of how signals can be processed through 'articulate' decomposition for learning to take place <emph> without <\emph> using NN's. Minsky is the reason I gave up on NNs ever being able to describe 'emergent learned behavior'. The concepts of consciousness and self-awareness are completely over rated and are of purely human interest, not engineering. The point here is: yes, the neural net model is cool; but only because it is easy to understand. They have been working on this since the 60's and have mostly failed to come up with anything other than math demos.)

So Jack, my global point is the wiki-author could be allowing personal biases to decide what a field is about or not. Is that right?
 
  • #5
sshzp, I welcome your citicism, but perhaps you could be a bit more constructive.

The moment you say 'dynamical' you mean a flow/difference mathematical mapping representation of a system.

I believe I represented it this way throughout the article. Perhaps my mention of ANN was distracting and I should remove it. But you did see the reference to Izhikivech's Dynamical Systems in Neuroscience, no? This is an important point about thresholds vs. resonating.

So the article seems more suited to 'some differences between ANN and dynamical neuroscience'.

I think I only bring that up in the beginning, but if you would like to point to the specific cases that bother you,

I am going to recommend the article to be merged with some other article on dynamical systems and completely rewritten. Its got way too many facts muddled up and tries to make facts of personal conjectures.

Well this is a vague criticism. Not very helpful, really.

Edit: The article is poorly written, ideas get thrown around everywhere. No structure and no clarity. Consider heavy revisions, and focus on improving single sections. (Written by a biologist? :^D)

Very vague, still. And don't you think it would be insulting to biologists for you to use them as an insult? I'm a physics graduate student. My only experience is with Morris Lecar networks. It's a work in progress. (I'm going to add a separate section on attractor networks).

My observation of irrelevance comes from constructed implications in the article such as "Even in this day and age of lightning communication, Dynamical Neuroscience didn't even receive it's own wiki article until 2010". For a good reason, obviously. Since the field is nascent

Which was the point...

It seems like a slap on the face of scientists who, say, model the neurochemistry dynamics and should be viewed as being dynamical neuroscientists as well.

This is a good point. You might have read it before I added that part.
I figure since you're spending so much time defending your position, you way as well give more specific, constructive criticism :P

thank you!
 
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  • #6
Well I don't want to go off-topic. Allow me however to reply to sshzp's comments:

I admire Pythagorean's efforts to make an effort at emphasizing the dynamics of the brain and did not feel it was poorly written. I do indeed have enormous confidence in non-linear dynamics and believe strongly it is the ultimate key in understanding how the brain works. However I am quite critical of the past 50 years of AI and agree they have failed miserably because their work has been based on models that are linear: transistors that are either "on" or "off", and the linear program. I do not believe the current implementation of neural networks will ever emerge artificial intelligence because they too are based on the current computer technology that is inherently linear and have always proposed that we will have to wait for a critical point in technology when someone creates a new qualitatively different device that is intrinsically non-linear. When these devices are then coupled in very complex ways to mimic the cortex, I have great faith this will lead to emergent properties that will be akin to real artificial intelligence.
 
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  • #7
sshzp4 said:
You don't study only 'learning and memory' type problems in 'dynamical neuroscience'

I really didn't mean to imply that, but if that's how you interpreted it then I need to rewrite the intro, because obviously it's made a terrible first impression on you.

My personal experience every time I tell people I work in Computational Neuroscience is they think I'm designing ANN, so I wanted to clear that misconception up.

you study the biological physics, chemical kinetics, electrochemistry, transport phenomena and emergent behavior of the systems as well.

I agree. I need to find a way to work this stuff in. I do have a section "beyond the neuron" to illustrate the point, but perhaps I need to make it clearer.

jackmell said:
I do indeed have enormous confidence in non-linear dynamics and believe strongly it is the ultimate key in understanding how the brain works.

I think this is too strong of a statement. It's not the ultimate key, but it is definitely a fruitful pursuit.
 
  • #8
Allow me please to contribute something concrete:

W. Freeman's article, "How the brain makes chaos to make sense of the world" attempts to model the olfactory bulb by a system of non-linear delay differential equations:

http://sulcus.berkeley.edu/FreemanWWW/manuscripts/IC8/87.html

Also, Terrence Senjowski suggested strange attractors may have some part in memory formation in the brain. As you know strange attractors are a hallmark of non-linear dynamics. Terrence is co-author of "The Computational Brain". I do not have the reference where he makes this suggestion however.

One final note: I'm sure you're aware of the "Blue Brain" project where an IBM group is attempting to model the cortex. My understanding is that their work is centered on the (non-linear) Hodgkin-Huxley equations and have plans as I understand it, to begin incorporating "history" in the form of likewise non-linear integro-differential equations. We are aware that neurons exhibit such a "history" phenomenon: their present behaviour is dependent on their past behavior.
 
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  • #9
@Pythagorean
"I figure since you're spending so much time defending your position, you way as well give more specific, constructive criticism :P "

I will leave that task for your advisors :). I love to bark at all things (I get paid to do that), but am in general too lazy to start the process of a detailed review (unless I get paid to do that).

Since you are still a student, your effort is great for a school project. But as the reviewer of a professional technical review article, the article is shoddy. If I stumbled across that article while just surfing the web, I would have added a significant section with choice abuses. Reviewing and being reviewed are both hard processes, but I am sure you will find out. (So best get obdurated to that feeling from receiving vague comments that leave it up to you to find out the implications :D)

@Jack -- I do hope you are correct. But I will still quote you on the following "I do not believe the current implementation of neural networks will ever emerge artificial intelligence but have always proposed that we will have to wait for a critical point in technology when someone creates a new qualitatively different device that is intrinsically non-linear", and describe that as a mere conjecture or prediction, not the current state of truth. We have been trying ever since the perceptrons were conceived to create Bayesian NNs to process statistical data. That's still a hypothesis. My point is, right now statistics and trained classification seem better approaches to modeling intelligent behavior. However, this view can be debated based on the background of the observer. Most CS people will claim statistics is better but EE folks will call NNs a happier approach.

And Jack, remember NNs are conceptually more closer to statistics and classification, and are usually used as blackbox algorithms. NLD using perceptrons might lead to non-deterministic behavior (the feared counterpart of deterministic chaos), which can only be analyzed statistically. Anyway, quite irrelevant for the geometer's topic, but good to think about.

Sid
 
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  • #10
ssh said:
I will leave that task for your advisorss [...] since you are still a student, your effort is great for a school project.

It's not a school project, nor do my advisors know about it.


But as the reviewer of a professional technical review article, the article is shoddy. If I stumbled across that article while just surfing the web, I would have added a significant section with choice abuses. Reviewing and being reviewed are both hard processes, but I am sure you will find out. (So best get obdurated to that feeling from receiving vague comments that leave it up to you to find out the implications :D)

Point taken. It has changed a bit since I posted this.

And to be honest, you've actually given me a lot more than vague comments. You've giving me an idea of how certain types of people interpret my article, and that comes with identifying your own biases and unspoken assumptions. I actually have some work to do thanks to you and other, more gentle critics.

but I should sleep on it.
 
  • #11
@ Jack -- Conjectures and hypothesis against a concrete theory constructed on experimental fact? You should use the term 'speculated' instead of 'suggested'. Wells speculated man could land on moon, gave him the privilege of being described as the progenitor of the idea for a long time. But 'gravity shutters' didn't work.

Speculation is merely the cautious way to claim that they said it first; if proven wrong they say it was 'mere speculation', otherwise its always an I told you so. Its a very dangerous form of academic fudgery.

EOT

Sid

Edit: Oh, I see the point of your last post. You were helping the geometer with references. I assumed it was an extension of your earlier comment. Anyway, never mind.
 
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  • #12
I think it would be a good idea to have a neurophysiologist comment about the article (seriously). I'd be curious to know what they think about the article. I am a big believer in constructive criticism. No way you could swing that Sid right? Just asking that's all. And you're right, I've expressed my personal opinions about how the brain should be approached. I apologize for going off-topic and should have concentrated on the writing instead. Sides, I have an etouffee to make now.
 
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  • #13
@ Jack: Oh I could try swinging that! :) When you have been criticized enough (for everything from a misplaced punctuation mark to the presence of a hyphen in a misleading place) all criticisms are just indicators of the presence of issues that lead thoughts astray off the topic at hand. The more vague a critique is or the more destructive it is, the more the indication that you haven't been able to get the idea across. So the nature of a critique usually gives you an idea of where the issues with your authorship lie (Assuming of course that the reviewer grasps the language of the discourse and there is no conflict of interest).
 
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  • #14
1) the page is all about neurons not brains, so should be called dynamic neuron science at most. Dynamical approaches to brains would cite the likes of Walter Freeman, Scott Kelso, Karl Friston, Stephen Grossberg, Paul Nunez, etc, etc.

2) the page is based on a fundamental misconception. Yes neurons/brains have a dynamic basis (like all biology), but what is important about them of course is the way they capture information. Talking about a purely "dynamic" approach is just wrong from the start (unless you have the explicit limited research ambition of studying the physiologic-dynamic aspects of their functioning).

Neural nets are a computational attempt to model what is going on (an informational basis to the information processing!). So there is room for a dynamical approach to information processing. Some people talk about hybrid disciplines like infodynamics.

But anyway, the page does not spell out where it sits on a spectrum of approaches (not that it is about "brain dynamics" as opposed to neuron physiology in the first place).
 
  • #15
apeiron said:
1) the page is all about neurons not brains, so should be called dynamic neuron science at most. Dynamical approaches to brains would cite the likes of Walter Freeman, Scott Kelso, Karl Friston, Stephen Grossberg, Paul Nunez, etc, etc.

As discussed with ssh, this is not the case, but it may be the result of bad communication. I may have changed the page to reflect this before you read it, but also note that I'm still in the process of adding sections beyond neurons. This is not, by any means, a complete page. I intend to add a holistic section.

Btw, the whole nervous system is of interest, not just the CNS.

2) the page is based on a fundamental misconception. Yes neurons/brains have a dynamic basis (like all biology), but what is important about them of course is the way they capture information. Talking about a purely "dynamic" approach is just wrong from the start (unless you have the explicit limited research ambition of studying the physiologic-dynamic aspects of their functioning).

This is the same case with neurobiology, neurophilosophy, and neurophysics, all of which are their own disciplines and have their own wiki articles. No one discipline accounts for all the aspects of the subject it studies. There are, however, many scientists, who are only trained in their field of analysis.

Neural nets are a computational attempt to model what is going on (an informational basis to the information processing!). So there is room for a dynamical approach to information processing. Some people talk about hybrid disciplines like infodynamics.

agreed...
 
  • #16
OK, major revisions, refined citations, added content. Please continue to point out overly speculative claims and suggest new sections or contet:

http://en.wikipedia.org/wiki/Dynamical_Neuroscience [Broken]

Section to add, yet:
Applications (both medical and theoretical)
Chaos and nature
more cognitive content

Possibly this:
http://www.scholarpedia.org/article/Dynamic_causal_modeling
 
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  • #17
It is looking better. But to focus things, what are you seeing as distinctive about "dynamical neuroscience" here?

To me, the central idea you want to articulate seems to be that neuroscientific approaches to explaining mind or cognitive function (the higher level stuff) has been based on a "too simple" model of the components. So a more accurate dynamical description of these components may serve as a better foundation for high level explanations.

If this is the case (I may just misread your intent) then it would be helpful to make a connection to the arguments that standard ANN modelling is too simplistic. And second, examples of modelling that makes use of more dynamical componentry.

The lurking thought when people stress dynamics is that there must be something big we have been missing by taking familiar linear, computational, atomistic approaches to modelling the neuron, and the brain. So if we go back to basics, we may finally unlock the secrets via some new dynamical principle.

I think this is true. But I don't personally think the secret exists "down in the neurons". I don't even think it exists in the collective behaviour of neurons or even, separately, at some whole brain level (as some like Nunez and Freeman sort of argued).

Instead, I believe these dynamical principles (actually they would be info-dynamical) would exist over all scales of neural organisation. They would be very general. Which is why I personally follow a systems science/theoretical biology/semiotics approach to modelling.

But anyway, the point I am trying to make is that you probably have a specific hypothesis about the reason for framing the research issues in the particular way you have. That is, we need to study neuron-level dynamics, component level dynamics, because somehow the secret we are missing can be found at this scale of mechanism. The existence of the page would make more sense if you spelt out this theoretical context.
 
  • #18
When I introduced myself to the neuroscience/brain/mind community here on physicsforums, I was really interested in the higher-order problems like consciousness and cognition, so you may be mixing those connotations in with my writing, knowing that I'm the author (of course, it's possible that I'm also "leaking philosophy" in my writing).

Dynamical neuroscience doesn't serve to be holistic. There are, of course, holistic dynamical approaches.

In some respects, the field is a lot like a blacksmith. The blacksmith makes lots of different things out of metal, mostly because he's good at working with metal. The things he makes may applied all kinds of different way, from helping, to killing, to hanging on your wall as art. He's not very concerned with how people apply it. As the market grows and diversifies, the blacksmiths may specialize (like focusing on a market that uses particular metals and cuts that are safe for children in nursery construction). So then the blacksmith begins to learn more about child care and nurseries since the market is there, and he can provide a higher quality product, tailored for a specific demographic.

a dynamical scientist works with dynamical systems, because they know about the machinery of dynamical systems (specifically, they're versed in nonlinear dynamics, which requires a good mathematical background). Many dynamical scientists are like your unfocused blacksmith, they are only interested in dynamical systems in general, they don't cater to one particular group. But neuroscience, obviously, has exploded with interest and technology in the last couple decades and so there is now a demographic for dynamical scientists, so it has become more efficient to specialize in neuroscience, and learn the subject along with it.

Dynamic neueroscience has a very large medical and physiological component too that make no guesses about the consciousness or other cognitive aspects. At a certain point, your questions will push you over the line to dynamical psychology (yeah, it's out there), which is not the topic I'm covering. Cognitive neuroscience is the acceptable in-between.

addendum:

and ANN's are still acceptable dynamical systems if their global constraints are such. It's just that each individual neuron is not dynamical. The interaction dynamics can be very dynamical, depending on the model.

addendum2:
examples of modelling that makes use of more dynamical componentry.

That's what the morris-lecar (which I summarized with equtions) and hodgkin-huxley models are, they focus more on the dynamics of singular neurons. They are based on resonance, not the digital all-or-none firing, but they still exhibit excitability (similar to all-or-none firing, but not quite the same) and can still be coupled together in a meaningful network.
 
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  • #19
Your focus still seems to be just on the cellular level, so it is not "neuroscience". That is one big source of confusion here. And there is already a wiki on biological neurons that you link to which is about a dynamical sub-discipline.
http://en.wikipedia.org/wiki/Biological_neuron_model


And to call it dynamical, I would expect a justification. Is is dynamical that ignores the emergence of computational features (which it sounds as though you are saying)? Is it dynamical as the way to explain emergent computational features (which is what people would expect)?
 
  • #20
apeiron said:
Your focus still seems to be just on the cellular level, so it is not "neuroscience". That is one big source of confusion here. And there is already a wiki on biological neurons that you link to which is about a dynamical sub-discipline.
http://en.wikipedia.org/wiki/Biological_neuron_model

This is a matter of personal availability, not focus. See "attractor networks" in my article and "cognitive neuroscience" with "hopfield networks". This is where I need input from people (that's why I noted that i need more for the cognitive neuroscience section) but remember that it has to have a dynamical basis (it has to have a nonlinear mathematical formulation that exhibits rich dynamics) and it has to be based on empirical observation (to be science, of course).

Remember that I take a reductionist approach (and also remember that I do not think our approaches are mutually exclusive, and in fact think they're beneficial in terms of synergy) so I'm already spent on what I can offer the page. I've had to do a lot of research to expand it as much as I have, and it will take more research to expand it more, but this is why I'm asking for input, because I'm not completely sure where to look.

Note also, that I'm still reviewing old discussions from you. I just came across Scott Kelso, which I'm going to look into to add.

And to call it dynamical, I would expect a justification. Is is dynamical that ignores the emergence of computational features (which it sounds as though you are saying)? Is it dynamical as the way to explain emergent computational features (which is what people would expect)?

I'm not sure those are directly relevant. Dynamical refers to the mathematics. This is mathematical biology, but more specified. Dynamics is a subject of math, neuroscience as a subject of biology. Of course, nowadays, (neuroscience is interdisciplinary).

It doesn't directly make a judgments about computationalism, emergence, etc. It does the actual analysis on the models and looks for realistic regimes that explain observed behavior. The problem is that the nature of the equations is not simple, there are thousands of regimes to look in (depending on how many dimensions and parameters your model has).
 
  • #22
Pythagorean said:
I'm not sure those are directly relevant. Dynamical refers to the mathematics. This is mathematical biology, but more specified. Dynamics is a subject of math, neuroscience as a subject of biology. Of course, nowadays, (neuroscience is interdisciplinary).

OK, I understand. But my point is that it is a fundamental mistake (arguably) to believe that it is possible to create a "proper" dynamical description, and from that derive the computational (or rather informational) aspects of the system in question.

This is a huge issue, widely discussed, most especially in mathematical biology (Rosen, Patttee, Salthe, Brier, etc). And also in developmental systems theory (Oyama, etc) - http://en.wikipedia.org/wiki/Developmental_systems_theory

So to put up a page that is "just dynamics" needs justification to make sense. Otherwise it sounds like you are taking a regressive step.

Again, to repeat, it has been argued as a no-go theorem that "just dynamics" can't give us a full story in neuroscience. Robert Rosen and Howard Pattee are the best sources here.

If you just want to highlight a class of nonlinear mathematical modelling, then that's great. I'm merely saying that from my perspective, it sounds really odd not to acknowledge the wider context of debate.

The cutting edge of modelling would be about how dynamical processes (which are well-modelled in terms of attractors, metastability, etc) are harnessed by informational ones (which is where semiosis, symbol-grounding, the epistemic cut, etc, come in).
 
  • #23
apeiron said:
OK, I understand. But my point is that it is a fundamental mistake (arguably) to believe that it is possible to create a "proper" dynamical description, and from that derive the computational (or rather informational) aspects of the system in question.

I don't believe that. I believe in an interdisciplinary approach. What you call a "systems approach" (btw, 'systems neuroscience' academically is a synthesis class, it's a lot like a 'final lesson', you integrate all the subdisciplines for research, you collaborate across the fields, so most actively researching neuroscientist are "systems" neuroscientists by default.

For instance, follow the Dynamical Neuroscience conferences which I cite:
http://neuro.dgimeetings.com/Home.aspx
to see the broad spectrum of contributing fields.

Anyway, with respect the viewpoint you keep projecting on me, I believe that all fields follow from each other in a... well, a dynamical way. It's not like all of psychology is going to be discovered from neurons or all off neurons will be understood solely from psychology; it's that development of both fields will provide insights to each other.

Dynamical sciences been successful in employing "reductionist" (that's a relative term) modeling to describe emergent cognitive proerties (again, see attractor networks in the article).

And as I've also demonstrated in the article (Gluck, in the cognitive neuroscience section) it works in reverse too, but that's not a dynamical example that I know of. I still mentioned hopfield networks though.

And in the intro:

"Information theory draws on thermodynamics in the development of infodynamics which can involve nonlinear systems, especially with regards to the brain."

So please point to specifically where you're confused.
 
  • #24
You think you know what you are talking about? Fine.
 
  • #25
Yes, I do know what I'm talking about here: my perspective. Which you are misrepresenting, and which is more aligned with your perspective than you realize.

The wiki is based on scientific contributions, which will take time to research and digest before all major perspectives are represented.
 
  • #26
  • #27
Pythagorean said:
Yes, I do know what I'm talking about here: my perspective. Which you are misrepresenting, and which is more aligned with your perspective than you realize.

The wiki is based on scientific contributions, which will take time to research and digest before all major perspectives are represented.

These statements are so contrary to the Wikipedia spirit that only this quotation is enough to justify a request for deletion of the article. Wikipedia is not a place where perspectives meet like in a debate, it is not a public place to express your views. I proposed the merge to Computational Neuroscience and the deletion of most of the content. Even the textbook you provide uses "dynamical systems in neuroscience" rather than "dynamical neuroscience". There is no justification in the litterature referenced to create a separate page for dynamical systems, which have been used throughout the history of what has been called computational neuroscience. The whole discussion here proves that you are trying to introduce your personal views in Wikipedia, which in itself is unnacceptable on top of all the fundamental debate behind it. Most people using non-linear equations in computational neuroscience do not define themselves as "dynamical neuroscientists".

jackmell said:
I think it would be a good idea to have a neurophysiologist comment about the article (seriously).

Now you have it :)


You can participate to the merger proposal vote here : http://en.wikipedia.org/wiki/Talk:Computational_neuroscience#Merger_proposal
 
  • #28
  • #29
OK, I've done some research, I found the proper name for my field: Neurodynamics.

Here's a bit about it's history:
http://resources.metapress.com/pdf-preview.axd?code=g384811610556546&size=largest

Here's what people are saying about it now (well, 9 years ago anyway):

Current Opinion in Neurobiology, August 2001, Volume 11, Issue 4. Neurodynamics: nonlinear dynamics and neurobiology: Henry D. I. Abarbanel, a and Michael I. Rabinovich

Abstract said:
"The use of methods from contemporary nonlinear dynamics in studying neurobiology has been rather limited.Yet, nonlinear dynamics has become a practical tool for analyzing data and verifying models. This has led to productive coupling of nonlinear dynamics with experiments in neurobiology in which the neural circuits are forced with constant stimuli, with slowly varying stimuli, with periodic stimuli, and with more complex information-bearing stimuli. Analysis of these more complex stimuli of neural circuits goes to the heart of how one is to understand the encoding and transmission of information by nervous systems."

-----

JFGariepy said:
These statements are so contrary to the Wikipedia spirit that only this quotation is enough to justify a request for deletion of the article. Wikipedia is not a place where perspectives meet like in a debate, it is not a public place to express your views. I proposed the merge to Computational Neuroscience and the deletion of most of the content. Even the textbook you provide uses "dynamical systems in neuroscience" rather than "dynamical neuroscience". There is no justification in the litterature referenced to create a separate page for dynamical systems, which have been used throughout the history of what has been called computational neuroscience. The whole discussion here proves that you are trying to introduce your personal views in Wikipedia, which in itself is unnacceptable on top of all the fundamental debate behind it. Most people using non-linear equations in computational neuroscience do not define themselves as "dynamical neuroscientists".

You took that post out of context. I differentiated between the article and my post. In my POST I was talking about my perspective. The WIKI article is supposed to be about the collective perspective of the members of the field (which I'm still struggling to perfect through my research, admittedly).
 
  • #30
Pythagorean said:
OK, I've done some research, I found the proper name for my field: Neurodynamics.

Here's a bit about it's history:
http://resources.metapress.com/pdf-preview.axd?code=g384811610556546&size=largest

Here's what people are saying about it now (well, 9 years ago anyway):

Current Opinion in Neurobiology, August 2001, Volume 11, Issue 4. Neurodynamics: nonlinear dynamics and neurobiology: Henry D. I. Abarbanel, a and Michael I. Rabinovich



-----



You took that post out of context. I differentiated between the article and my post. In my POST I was talking about my perspective. The WIKI article is supposed to be about the collective perspective of the members of the field (which I'm still struggling to perfect through my research, admittedly).

Well at least you see that the questions I raised concerning the name of your field and its exact definition was justified and it wasn't bad faith on my part. It's very important to watch for these things on Wikipedia if we don't want the encyclopedia to become a live discussion forum where people define things the way they want. Good luck with your future contributions.
 
  • #32
Pythagorean said:
Here's a paper highlghting the specific advantages of a dynamical view:

http://sulcus.berkeley.edu/FreemanWWW/manuscripts/IC13/90.html

That was 20 years ago and the other, nine. Can you cite a more recent opinion of neuroscientist on the matter of using non-linear dynamics, chaos theory, strange attractors, emergence, and self-organization as tools for understanding brain function?

Have you seen the brain series on Charlie Rose? I just caught a part of episode 10 yesterday. I'd be interested in what those guys think about neurodynamics. Maybe even you can contact Charlie and ask him if he could create an episode about neurodyanmics. Get Freeman in there maybe. Here's the link:

http://www.charlierose.com/view/collection/10702 [Broken]
 
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  • #33
jackmell said:
That was 20 years ago and the other, nine. Can you cite a more recent opinion of neuroscientist on the matter of using non-linear dynamics, chaos theory, strange attractors, emergence, and self-organization as tools for understanding brain function?

Freeman actually impressed me the most out of all the "dynamicists" who sprang up in the 80s/90s. But equally, he showed that attractors and other "straight non-linear models" lacked real bite. They are good for making analogies, but not then for producing actual predictive models.

So just as we would say the brain is not a Turing computer, we can also say it is not a straight dynamical system either.
 
  • #34
jackmell:

strictly neuron behavior
Here's some more recent papers that make use of nonlinear dynamics to understand neuron behavior itself (generally, drawing no conclusions about cognitive aspects). These have been productive in medical and general physiological understanding.

from the nonlinear dynamics journal:
http://www.springerlink.com/content/n2567128x6372603/

Izhikevich gives his opinions in the text, "Dynamical Systems in Neuroscience" written in 2007:
http://mitpress.mit.edu/catalog/item/default.asp?ttype=2&tid=11063

http://www2.gsu.edu/~matals/ashilnikov_cv.pdf - Shilinikov's CV (scroll down to publications. You see a lot of direct medical applications for nonlinear dynamics)On the more cognitive side:

http://www.mitpressjournals.org/doi/abs/10.1162/jocn.1995.7.4.512
(A Dynamic Systems Approach to the Development of Cognition and Action)

Lewis, Marc D. (2005) Bridging emotion theory and neurobiology through dynamic systems modeling. BEHAVIORAL AND BRAIN SCIENCES; 28, 169–245
 
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  • #35
apeiron said:
Freeman actually impressed me the most out of all the "dynamicists" who sprang up in the 80s/90s. But equally, he showed that attractors and other "straight non-linear models" lacked real bite. They are good for making analogies, but not then for producing actual predictive models.

Apeiron, can you provide the reference where he "showed" this please? I do not recall him taking this position in the paper I studied some time ago, "How the brain makes chaos to make sense of the world."

Even so, I'm skeptical of his appraisal and remain unperturbed in my belief that mind can emerge from equation.

Pythagorean, thank you for posting those references.
 
<h2>1. What is dynamical neuroscience?</h2><p>Dynamical neuroscience is a field of study that combines principles from neuroscience and dynamical systems theory to understand the complex dynamics of the brain and the nervous system. It seeks to explain how the brain processes information and generates behavior through the interactions of neurons and neural networks.</p><h2>2. What are the key concepts in dynamical neuroscience?</h2><p>The key concepts in dynamical neuroscience include nonlinear dynamics, emergence, self-organization, and complex systems. Nonlinear dynamics refers to the study of systems that exhibit behavior that cannot be explained by simple linear relationships. Emergence refers to the phenomenon where complex behaviors and properties arise from the interactions of simpler components. Self-organization refers to the ability of systems to spontaneously organize and adapt to changing conditions. Complex systems refer to systems that have many interacting components and exhibit emergent behavior.</p><h2>3. How is dynamical neuroscience different from traditional neuroscience?</h2><p>Traditional neuroscience focuses on understanding the brain through reductionist approaches, breaking it down into smaller components and studying them in isolation. Dynamical neuroscience, on the other hand, takes a holistic approach and studies the brain as a complex system, emphasizing the interactions between different components and how they give rise to emergent behaviors.</p><h2>4. What are some applications of dynamical neuroscience?</h2><p>Dynamical neuroscience has many applications, including understanding brain disorders such as epilepsy and Parkinson's disease, developing brain-computer interfaces, and improving our understanding of consciousness and cognition. It also has potential applications in artificial intelligence and robotics, as it provides insights into how complex systems can learn and adapt to their environment.</p><h2>5. How does dynamical neuroscience contribute to our understanding of the brain?</h2><p>Dynamical neuroscience offers a new perspective on how the brain works by emphasizing the importance of nonlinear dynamics and complex systems. It helps us understand how the brain processes information, generates behavior, and adapts to changing environments. It also provides a framework for studying the brain as a dynamic and adaptive system, rather than a static and fixed entity.</p>

1. What is dynamical neuroscience?

Dynamical neuroscience is a field of study that combines principles from neuroscience and dynamical systems theory to understand the complex dynamics of the brain and the nervous system. It seeks to explain how the brain processes information and generates behavior through the interactions of neurons and neural networks.

2. What are the key concepts in dynamical neuroscience?

The key concepts in dynamical neuroscience include nonlinear dynamics, emergence, self-organization, and complex systems. Nonlinear dynamics refers to the study of systems that exhibit behavior that cannot be explained by simple linear relationships. Emergence refers to the phenomenon where complex behaviors and properties arise from the interactions of simpler components. Self-organization refers to the ability of systems to spontaneously organize and adapt to changing conditions. Complex systems refer to systems that have many interacting components and exhibit emergent behavior.

3. How is dynamical neuroscience different from traditional neuroscience?

Traditional neuroscience focuses on understanding the brain through reductionist approaches, breaking it down into smaller components and studying them in isolation. Dynamical neuroscience, on the other hand, takes a holistic approach and studies the brain as a complex system, emphasizing the interactions between different components and how they give rise to emergent behaviors.

4. What are some applications of dynamical neuroscience?

Dynamical neuroscience has many applications, including understanding brain disorders such as epilepsy and Parkinson's disease, developing brain-computer interfaces, and improving our understanding of consciousness and cognition. It also has potential applications in artificial intelligence and robotics, as it provides insights into how complex systems can learn and adapt to their environment.

5. How does dynamical neuroscience contribute to our understanding of the brain?

Dynamical neuroscience offers a new perspective on how the brain works by emphasizing the importance of nonlinear dynamics and complex systems. It helps us understand how the brain processes information, generates behavior, and adapts to changing environments. It also provides a framework for studying the brain as a dynamic and adaptive system, rather than a static and fixed entity.

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