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.
  • #36
jackmell said:
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.

I meant he showed me (by his failure). I talked to Freeman and others like Friston and Kelso a lot at the time. They had a well motivated approach. But it did not pan out in my opinion. It did not achieve lift off as hoped.

But "son of dynamical systems" still could. That's why I would keep track of guys like Friston who are trying to get some blend of dynamic and computational principles, as in the bayesian brain model.
 
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  • #37
This is anecdotal, but from my experience, one of the great things about defining a system with a set of nonlinear differential equations, is that (because of the nature of nonlinearity) you no longer need to use algorithms to describe different behavior.

That is, you don't need to make a bunch of if statements when you're organizing the behavioral structure of a system. Instead, bifurcations already exist in the equation themselves. All relevant behaviors are contained in the system of equations and it's a matter of what parameter space you're in, so all you have to do is adjust the proper parameter values and the appropriate behavior is described by the equation.

We've already gained a lot of ground (in terms of elegance and simplicity) by avoiding algorithms (which, to me, are patchwork... you can describe nearly anything with a long list of conditional algorithms, but it's not as intuitive or easy to manage as a system of two or three differential equations that can be written in two or three lines).
 
  • #38
oh, by the way, here's the weblog of Markus Dahlem, who uses the nonlinear approach to understanding migraine's in terms of volume transmission:
http://mdlabblog.blogspot.com/

Volume transmission is an extracellular interaction between neurons that don't utilize synapses. Some examples would be electromagnetic field effects between neurons and neurotransmitter concentrations.
 
  • #39
An article of Izhikevich (I have his book, Dynamical Systems in Neuroscience)

http://ieeexplore.ieee.org/stamp/stamp.jsp?tp=&arnumber=1333071

a Quote from the conclusion:

As the reader can see in Fig. 2, many models of spiking neurons
have been proposed. Which one to choose? The answer depends
on the type of the problem. If the goal is to study how the
neuronal behavior depends on measurable physiological parameters,
such as the maximal conductances, steady–state (in)activation
functions and time constants, then the Hodgkin–Huxleytype
model is the best. Of course, you could simulate only tens
of coupled spiking neurons in real time.
In contrast, if you want to simulate thousands of spiking neurons
in real time with 1 ms resolution, then there are plenty of
models to choose from. The most efficient is the I&F model.
However, the model cannot exhibit even the most fundamental
properties of cortical spiking neurons, and for this reason it
should be avoided by all means. The only advantage of the I&F
model is that it is linear, and hence amenable to mathematical
analysis. If no attempts to derive analytical results are made,
then there is no excuse for using this model in simulations.
The quadratic I&F model is practically as efficient as the
linear one, and it exhibits many important properties of real neurons,
such as spikes with latencies, and bistability of resting and
tonic spiking modes. However, it is 1-D, and hence, it cannot
burst and cannot exhibit spike frequency adaptation. Thus, it can
be used in simulations of cortical neural networks only when biological
plausibility is not a great concern.
 
  • #40
Network Modeling of Epileptic Seizure Genesis in Hippocampus
Somayeh Raiesdana, S. Mohammad R. Hashemi Golpayegani, Member, IEEE, and S. Mohammad P. Firoozabadi

Proceedings of the 4th International SaD1.24
IEEE EMBS Conference on Neural Engineering
Antalya, Turkey, April 29 - May 2, 2009

Based on the use
of mathematical nonlinear models of neuronal networks, it is
possible to formulate hypotheses concerning the
mechanisms by which a given neuronal network can switch
between qualitatively different types of oscillations. This
switching behavior is a dynamical paradigm in epileptic
seizure when e.g. an EEG characterized by alpha rhythmic
activity suddenly changes into a spike- burst pattern. This
transition, however, depends on input conditions and on
modulating parameters where often even a subtle change in
one or more parameters can cause a dramatic change in the
behavior of neural circuits. This sensitivity to initial
condition or to a small perturbation is the major hallmark of
nonlinearity and chaos. Nowadays, modeling neuronal
ensemble is one of the most rapidly developing fields of
application of nonlinear dynamics and the success of such
models depends on the universality of the underlying
dynamical principles.
Epilepsy is a brain disorder characterized by periodic and
unpredictable seizures mediated by the recurrent
synchronous firing of large groups of neurons in the cortex
and seizure represents transitions of an epileptic brain from
its normal less ordered (chaotic) interictal state to an abnormal
(more ordered) ictal state
 
  • #41
"Lectures in Supercomputational Neuroscience Dynamics in Complex Brain Networks"

From Series: "Understanding Complex Systems"

Complex Systems are systems that comprise many interacting parts with the ability to generate a new quality of macroscopic collective behavior the manifestations
of which are the spontaneous formation of distinctive temporal, spatial or functional
structures. Models of such systems can be successfully mapped onto quite diverse
“real-life” situations like the climate, the coherent emission of light from lasers,
chemical reaction-diffusion systems, biological cellular networks, the dynamics of
stock markets and of the internet, earthquake statistics and prediction, freeway traf-
fic, the human brain, or the formation of opinions in social systems, to name just
some of the popular applications.
Although their scope and methodologies overlap somewhat, one can distinguish
the following main concepts and tools: self-organization, nonlinear dynamics, synergetics, turbulence, dynamical systems, catastrophes, instabilities, stochastic processes, chaos, graphs and networks, cellular automata, adaptive systems, genetic algorithms and computational intelligence.
http://www.springerlink.com/content/t7u1m22m0116/front-matter.pdf
 
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  • #43
Subdiffusion and Superdiffusion in the biological sciences:

http://www.cell.com/biophysj/abstract/S0006-3495(09)00983-7
http://en.wikipedia.org/wiki/Anomalous_diffusion
http://www.cell.com/biophysj/abstract/S0006-3495(11)00877-0

Sub/superdiffusive systems are fractal objects, their derivatives being non-integer. This also means they don't depend just on nearest neighbors, but all other members of the ensemble!

Very expected from a dynamical systems perspective!

http://arxiv.org/ftp/math-ph/papers/0311/0311047.pdf

I wonder if these could be used to model modulation in neural networks:

http://arxiv.org/abs/0805.3769v1
 
  • #44
You probably know this but your wiki article is no longer there. Why?
 
  • #45
Nano-Passion said:
You probably know this but your wiki article is no longer there. Why?

reading the posts in this thread by JFGariepy might help understand that. I think though, that I started too early. The dynamical systems approach to neuroscience is still developing and it makes it difficult to comment on. It is the physicist's approach to computational neuroscience, so it could be integrated into the computational neuroscience page.

Instead I decided to contribute at a lower level, so I made this page:

http://en.wikipedia.org/wiki/Morris–Lecar_model

This is a popular model in computational neuroscience, based on the physics of real neurons; the Hodgkin Huxley model is the original, but this model reduces the dimensions in half for faster computation at the cost of simplifying assumptions.
 
  • #46
Pythagorean said:
reading the posts in this thread by JFGariepy might help understand that. I think though, that I started too early. The dynamical systems approach to neuroscience is still developing and it makes it difficult to comment on. It is the physicist's approach to computational neuroscience, so it could be integrated into the computational neuroscience page.

Instead I decided to contribute at a lower level, so I made this page:

http://en.wikipedia.org/wiki/Morris–Lecar_model

This is a popular model in computational neuroscience, based on the physics of real neurons; the Hodgkin Huxley model is the original, but this model reduces the dimensions in half for faster computation at the cost of simplifying assumptions.

Oh.. so then what would be the difference between theoretical and dynamical neuroscience?
 
  • #47
Nano-Passion said:
Oh.. so then what would be the difference between theoretical and dynamical neuroscience?

Theoretical neuroscience is an umbrella term encompassing many current approaches. Dynamical approach to neuroscience is a particular theoretical approach that utilizes time-smooth continuous equations to describe neural events as the neural systems evolve through state-space. They are structurally deterministic, but noise terms and random processes can be integrated into them. There's also symbolic dynamics which utilize the Markov partition.

A large part of dynamical systems approach is studying quantities geometrically (i.e you draw the average trajectories of your system and you begin to see structures that have functional meaning in the state-space of the system). You generally measure quantities of the system like: the lyapunov constant, the natural measure, the basin of attraciton, etc.
 
  • #48
Hmmm, but is there such a thing as non-dynamical neuroscience?

I can imagine that some of the "optimization" approaches are considered non-dynamical by some. But that would be like saying statistical mechanics which maximizes free energy is non-dynamical, and place Boltzmann's work on kinetic theory out of the realm of statistical mechanics, which is strictly correct, but surely not your intention. Also many dynamical systems can be described as optimal (but not uniquely) through the use of Lagrangians (maybe take a look at Enzo Tonti's work for how far this can go).

Even if you consider anatomy as non-dynamical, I'm sure most anatomists do their work because they know how it fits in with physiology. Similarly, most physiologists know how important network topology (ie. anatomy) is for interpreting physiology. It's the same at a lower level in chemistry, where no one would interpret the diagram A+B→C as non-dynamical because the rate constants were not explicitly included.

Incidentally, I have read books where it is said that control or systems theory goes beyond dynamics, in the strictly true sense that most dynamics deals with autonomous equations. But I'm sure you'd disagree with that!
 
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  • #49
atyy said:
Incidentally, I have read books where it is said that control or systems theory goes beyond dynamics, in the strictly true sense that most dynamics deals with autonomous equations. But I'm sure you'd disagree with that!

There is definitely a live issue here. It seems obvious both that everything is grounded in biological dynamics, yet also that dynamics is only half the story. Therefore some kind of hybrid is the "higher view".

The same issue arise in biology, with the fundamental division between genes and organisms, or replication and metabolism. And there have been continuing efforts to marry the two sides, as in systems biology, relational biology, evo-devo, biosemiotics, etc.
 
  • #50
dynamics in this sense refers to the dynamical systems theory (DST) approach, which entails nonlinear equations that generally have no analytical solution.

Much quantitative scientific work relies on the expectation of equilibrium which allows for linear equations. Thus, you can take the system apart into its components, solve each one, and put them back together, because they obey the superposition principle.

Nonlinear systems are more general (if you make particular terms first order or particular constants zero, you can reduce the equations to linear). They do not obey superposition principle (so you will often hear the sum of the parts is not equal to the whole).

So naturally, dynamical systems are closer to the reality, since they make less simplifying assumptions (particularly the assumption of equilibrium and superposition) but previously to the computer age scientists would have had to derive, literally, thousands of equations... the "accounting" errors associated with this kind of work with paper and pen wouldn't even make it worth it. And these solution would not be analytical, they would be numerical.

Poincare discovered a way to geometrically assert things about the system (it's stable points, where it attracts solutions in state space, where it repels solutions, etc) without explicitly finding solutions. So this is what was done before computers with systems that had low enough dimension that you could visualize it geometrically.

So dynamical systems theorists are often sometimes called "geometers" because a major emphasis is visualizing the system in state space. The actual "dynamical" word only serves the purpose of a coup against the equilibrium assumption.

But yeah, there is no panacea. No one approach will tell the whole story of anything, ever. So there's no reason to jump in the DST bucket and ignore the rest of the world.
 
  • #51
Pythagorean said:
Much quantitative scientific work relies on the expectation of equilibrium which allows for linear equations.

Pythagorean said:
Poincare discovered a way to geometrically assert things about the system (it's stable points, where it attracts solutions in state space, where it repels solutions, etc) without explicitly finding solutions.

I'm not sure that ideas of equilibria and linearity are morally distinct from fixed points and whether they are attractive or repelling. After all, fixed points are equilibria, and whether they are attractive or repelling can often be found by linearization (one has to go to higher orders in the "marginal" cases).

Also, maybe the attractor is irrelevant http://prl.aps.org/abstract/PRL/v60/i26/p2715_1

Pythagorean said:
But yeah, there is no panacea. No one approach will tell the whole story of anything, ever. So there's no reason to jump in the DST bucket and ignore the rest of the world.

But couldn't one say dynamics is the panacea because it includes the rest of the world? By including non-autonomous systems and Lie brackets the geometric viewpoint can be extended to control or systems theory, and there is a relationship to symbolic dynamics via generating partitions and markov partitions. Even classical mechanics has a link to probability theory via Liouville's theorem, and a link to optimality via Lagrangians. So perhaps "dynamical neuroscience" is redundant - the integrate-and-fire neuron is more than http://homepages.inf.ed.ac.uk/mvanross/reprints/lapique2007.pdf, and the HH equations are in every textbook.
 
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  • #52
apeiron said:
There is definitely a live issue here. It seems obvious both that everything is grounded in biological dynamics, yet also that dynamics is only half the story. Therefore some kind of hybrid is the "higher view".

The same issue arise in biology, with the fundamental division between genes and organisms, or replication and metabolism. And there have been continuing efforts to marry the two sides, as in systems biology, relational biology, evo-devo, biosemiotics, etc.

I had a much dumber idea in mind than what you are mentioning. The control or systems view merely meant including non-autonomous systems. In the continuous time and degrees of freedom case, this is still Pythagorean's differential geometric viewpoint.

I guess what you are saying, which is true, is that the differential geometric (or differential topological) viewpoint alone isn't so useful for defining useful emergent variables. For example, in certain variables, the "attractor" could be a limit cycle, while in "coarse grained" variables, the same "attractor" would be described by a fixed point. Also, one may choose to discretize time and use a generating partition or markov partition to make a link to symbolic dynamics. And that's of course just the beginning. So perhaps one could say that dynamics is everything, but so is emergence. How's that for an attempt to paraphrase your "higher view" :tongue2:
 
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  • #53
atyy said:
I'm not sure that ideas of equilibria and linearity are morally distinct from fixed points and whether they are attractive or repelling. After all, fixed points are equilibria, and whether they are attractive or repelling can often be found by linearization (one has to go to higher orders in the "marginal" cases).

Also, maybe the attractor is irrelevant http://prl.aps.org/abstract/PRL/v60/i26/p2715_1

Fixed points are equilibria, but a truly chaotic system never actually reaches the fixed points. Most interesting fixed points are wildly unstable, like a pencil standing on it's tip. And of course, as you are hinting at, the linearization is an approximation.

But let's say I use this linearization to find the fixed points of my system. Then I run the actual numerical simulation. The simulation does not rely on the linearized fixed point. I would overlay the two different sources in a plot to make qualitative assertions about the behavior of the system.


But couldn't one say dynamics is the panacea because it includes the rest of the world? By including non-autonomous systems and Lie brackets the geometric viewpoint can be extended to control or systems theory, and there is a relationship to symbolic dynamics via generating partitions and markov partitions. Even classical mechanics has a link to probability theory via Liouville's theorem, and a link to optimality via Lagrangians.

Does that cover life, the universe, and everything, then? :)

DST is a powerful and versatile tool. I'm often tempted by the idea that DST will help bridge quantum and classical through quantum chaos. But I also don't hold my breath, because people have been really excited about DST for 40 or so years now.


So perhaps "dynamical neuroscience" is redundant - the integrate-and-fire neuron is more than http://homepages.inf.ed.ac.uk/mvanross/reprints/lapique2007.pdf, and the HH equations are in every textbook.

Is integrate-and-fire dynamical? I thought it was a linear superposition...?

I don't know whether Hodgkins and Huxley were dynamical systems theorists. I don't think they were; I was under the impression they were just modeling currents and recorded what they got. The equations just happened to be non-linear.

It appears to me that it was dynamical systems theorists who picked up the empirical model and ran the barrage of dynamical tests on it, and what they found was that the system was really quite fitting to all the language that had been developed and found that the Hodgkin Huxley system was chaotic (which had a lot of implications for irregularity and diversity in biological systems).
 
  • #54
Pythagorean said:
Does that cover life, the universe, and everything, then? :)

Yes:)

Pythagorean said:
Is integrate-and-fire dynamical? I thought it was a linear superposition...?

Well, it has a terrible nonlinearity that makes it infinite dimensional. Yet it can be obtained as an approximation of the HH equations.

Pythagorean said:
I don't know whether Hodgkins and Huxley were dynamical systems theorists. I don't think they were; I was under the impression they were just modeling currents and recorded what they got. The equations just happened to be non-linear.

It appears to me that it was dynamical systems theorists who picked up the empirical model and ran the barrage of dynamical tests on it, and what they found was that the system was really quite fitting to all the language that had been developed and found that the Hodgkin Huxley system was chaotic (which had a lot of implications for irregularity and diversity in biological systems).

Are you also not counting Newton as a dynamical systems theorist?
 
  • #55
Pythagorean said:
But yeah, there is no panacea. No one approach will tell the whole story of anything, ever. So there's no reason to jump in the DST bucket and ignore the rest of the world.
Pythagorean,

An aside, sort of reminds you of particle physics now, doesn't it ?

Rhody...
 
  • #56
atyy said:
Yes:)



Well, it has a terrible nonlinearity that makes it infinite dimensional. Yet it can be obtained as an approximation of the HH equations.



Are you also not counting Newton as a dynamical systems theorist?

Poincare really developed the first tools at the turn of the 19th century.
 
  • #57
atyy said:
So perhaps one could say that dynamics is everything, but so is emergence. How's that for an attempt to paraphrase your "higher view" :tongue2:

I agree that non-linearity is the generalisation of linearity, and so any possible linearity can be treated as emergent. Dynamics must be basic in that sense.

But then there is the aspect of living systems which a dynamical description simply does not see in a useful theory sense, even if it may be able to replicate or simulate it fully (and "unknowingly).

The analogy is the hardware and software of a computer. The hardware is a material system. It changes state in some fashion. You could completely describe all that activity in material/dynamical language. You would be correct and complete in some sense. But you would not have a model that can take one state of a finite state automaton and predict its next state. It is the logic embedded in the software that is causing the state mapping. The material/dynamical description just cannot see the rules and data values that determine the running of the program.

So dynamics can describe spikes, but what describes what the spikes mean? The processes generating the spikes may be material, but the processes regulating the spikes may be informational.

The problem for neuroscience is whether to just model the informational view, just model the material view, model both as two distinct disciplines, or model both in some proper connected way.

It is a tricky business because the hardware and software of a computer are pretty easy to distinguish (OK, with microcode, it gets fuzzy). But with neurons, columns and cortical areas, meaning and medium are thoroughly mixed. As in a neural network, but far more so. You need some real strong principles to get in there and dissect apart the two aspects of what is going on.

So there is no doubt that a spike, for example, is a dynamical event. But it is just as clearly an informational event. Do you then seek to (1) ignore one of these aspects, (2) unify them in a single description, or (3) formalise the relationship between them in a way that is itself maximally general and thus "a law of nature"?
 
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  • #58
The idea that atyy proposes is that you use Markov partitions and symbolic dynamics to represent the more abstract semiotics; they would represent your informational classification of dynamical events.
 
  • #59
Pythagorean said:
The idea that atyy proposes is that you use Markov partitions and symbolic dynamics to represent the more abstract semiotics; they would represent your informational classification of dynamical events.

This is an informational way of modelling dynamical processes. So not what I am talking about.
 
  • #60
Pythagorean said:
Poincare really developed the first tools at the turn of the 19th century.

Hmmm, that's a very narrow definition of dynamical systems theory. It's morally ok in some sense, since Poincare is rightly regarded as the father of the topological approach to differentiable dynamics. While acknowledging you have a point, it does boggle my mind that you could exlcude Newton. Even KAM theory had its roots in the Hamilton-Jacobi formulation of mechanics, and whether action-angle variables (invariant tori in the modern language) exist.

apeiron said:
So there is no doubt that a spike, for example, is a dynamical event. But it is just as clearly an informational event. Do you then seek to (1) ignore one of these aspects, (2) unify them in a single description, or (3) formalise the relationship between them in a way that is itself maximally general and thus "a law of nature"?

Pythagorean said:
The idea that atyy proposes is that you use Markov partitions and symbolic dynamics to represent the more abstract semiotics; they would represent your informational classification of dynamical events.

I was really taking the particle physics point of view, as Rhody says!

Basically, there are not just 2 domains of description, but many. Each domain has its regime of validity, and degrees of freedom. A domain is always defined by subjective human interaction. This is true in thermodynamics, where the time scale of observation enters fundamentally in whether we accept something as in equilibrium or changing. It is also true in music which has no meaning played to a hydrogen atom, but does when played to a human being who uses emergent degrees of freedom such as pitch, rhythm, harmony, sonata form, expectation, frustration, resolution. The point regarding markov partitions was not to be over generalized, it simply meant that the relationship between two domains, in which one is a dynamical system describable by a diffeomorphism, is not necessarily a restriction of the system to a submanifold. As an analogy, Kadanoff-Wilson coarse graining provides one type of emergence in particle physics, but does not (in its simplest form) include other types such as holographic emergence.
 
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  • #61
atyy said:
Basically, there are not just 2 domains of description, but many.

On pragmatic grounds, yes, we are allowed to create as many modelling paradigms as we wish. Models are free inventions of the human mind, so there is no limit on how creative we can get, or how finely we wish to divide the cake.

But on fundamental grounds - which I thought we were debating - in fact the reductionist goal is to reduce everything in reality to a single common basis (a TOE), and the rejoinder from a systems perspective is in fact that instead we always seem to end up with dichotomies, two polar alternatives that seem have equal pull on our imaginations.

So should we reduce all neuroscience to dynamics, or to computation? Or should we unite the two by honouring their fundamental differences?

In theoretical biology, the systems view is understood. In theoretical neuroscience, not so much :smile:.

That does not mean there are not in fact multiple modelling paradigms. Just that a modelling fundamentalist would expect them to be arranged in a hierarchy so that they would still all "talk to each other". And then a reductionist would expect this hierarchy to work bottom-up - from some actual physical/material/dynamical TOE. While a systems thinker accepts that this hierarchy has in fact its two poles - so the semiotic/formal/computational is also fundamental in the way it anchors the other end of the spectrum.

In this way, we have both your "many models" as the stuff which fills the spectrum, and then the two fundamental poles needed to anchor that hierarchy.

The alternative view would be that of extremist social constructionism - models are just all human inventions, none with any more claim to fundamentality than any others. We would have a patternless mosaic, a space of modelling fragments each with local application but no global coherence.

So be careful what you wish for!
 
  • #62
apeiron said:
That does not mean there are not in fact multiple modelling paradigms. Just that a modelling fundamentalist would expect them to be arranged in a hierarchy so that they would still all "talk to each other". And then a reductionist would expect this hierarchy to work bottom-up - from some actual physical/material/dynamical TOE. While a systems thinker accepts that this hierarchy has in fact its two poles - so the semiotic/formal/computational is also fundamental in the way it anchors the other end of the spectrum.

In this way, we have both your "many models" as the stuff which fills the spectrum, and then the two fundamental poles needed to anchor that hierarchy.

The alternative view would be that of extremist social constructionism - models are just all human inventions, none with any more claim to fundamentality than any others. We would have a patternless mosaic, a space of modelling fragments each with local application but no global coherence.

I was hoping for the last view, but also with global coherence.
 
  • #63
atyy said:
I was hoping for the last view, but also with global coherence.

OK, so what is the nature of that coherence exactly?

Both the conventional reductionist and the systems view would expect coherence from a hierarchical arrangement of models that all "talk to each other" across their levels.

That in itself implies a common language - and information theory is emerging as that standard coin of exchange between theory domains. (Whereas more traditionally, a scientific coherence was claimed because "everything was made of the same kind of ultimate stuff" - science being a materialistic discourse.)

So you have the differentiation of models into levels of a hierarchy, and the integration of these models through some common language, some standard unit of exchange. How it works out in all its gory details is still debatable, but the general model of how global coherence would be achieved by the scientific enterprise seems both explicit and widely accepted. Witness the angry rejection of PoMo commentaries in the Philosophy of Science.

So if you are not taking this hierarchical approach to a universe of models, then exactly how do you imagine a coherence being achieved?

And further, are you claiming that the current patchwork of models is not actually connected in this fashion - if albeit loosely and imperfectly?
 
  • #64
atyy said:
Hmmm, that's a very narrow definition of dynamical systems theory. It's morally ok in some sense, since Poincare is rightly regarded as the father of the topological approach to differentiable dynamics. While acknowledging you have a point, it does boggle my mind that you could exlcude Newton. Even KAM theory had its roots in the Hamilton-Jacobi formulation of mechanics, and whether action-angle variables (invariant tori in the modern language) exist.

We can agree on all kinds of observations, but where we divide and categorize sets of observations is where we have conflicts ("It's QM", "no, it's CM!") or ("it's blue", "no, it's indigo!").

I don't consider Einstein a quantum physicist either; I think Newton and Einstein are both unique cases. They are pretty much our (i.e. society's) ideal vision of a scientist as you really can't box them up as this or that. Of course, I feel the same way about people like Poincare and Erdos :) they're just not as popular to the general public.

I was really taking the particle physics point of view, as Rhody says!

Well, I guess to me, symbolic dynamics means you take a particular state of the whole system of particles to be an emergent qualitative state. And while the dynamical system really has infinite states, you could (as an example) partition the phase volume into two and call one state "1" and the other state "0".

But I have no experience actually handling Markov partitions, so this is just my impression from reading literature that's full of cumbersome jargon.
 
  • #65
apeiron said:
OK, so what is the nature of that coherence exactly?

Both the conventional reductionist and the systems view would expect coherence from a hierarchical arrangement of models that all "talk to each other" across their levels.

That in itself implies a common language - and information theory is emerging as that standard coin of exchange between theory domains. (Whereas more traditionally, a scientific coherence was claimed because "everything was made of the same kind of ultimate stuff" - science being a materialistic discourse.)

So you have the differentiation of models into levels of a hierarchy, and the integration of these models through some common language, some standard unit of exchange. How it works out in all its gory details is still debatable, but the general model of how global coherence would be achieved by the scientific enterprise seems both explicit and widely accepted. Witness the angry rejection of PoMo commentaries in the Philosophy of Science.

So if you are not taking this hierarchical approach to a universe of models, then exactly how do you imagine a coherence being achieved?

And further, are you claiming that the current patchwork of models is not actually connected in this fashion - if albeit loosely and imperfectly?

Well, what I'm saying is morally related to hierarchical thinking - but with no model being fundamental, and no hierarchy - more a patchwork of coordinate charts - but even then not quite since there is no standard unit of exchange (except the human mind).
 
  • #66
apeiron said:
This is an informational way of modelling dynamical processes. So not what I am talking about.

That is a more of a distracting coincidence, I was actually referring to the subjectivity allowed of the investigator to define the partitions of the system himself. The investigator is free to implement a hierarchical approach... and for particular kinds of systems (at least) if we define the partition around the bifurcations of the system, we cannot even avoid adhering to heirarchy (the bifurcation branches) and its relationship to scale (the bifurcation parameter).
 
  • #67
atyy said:
Well, what I'm saying is morally related to hierarchical thinking - but with no model being fundamental, and no hierarchy - more a patchwork of coordinate charts - but even then not quite since there is no standard unit of exchange (except the human mind).

But is this your goal, or just a description of best likely outcome? We were talking about goals (even you expressed coherence as a hope of yours).

And your comment about there being no unit of exchange apart from the human mind is baffling. Units of exchange are what a modelling mind would create, not what they would "be".

It might help if you could supply references to your brand of epistemology here.

For instance, an example of the adoption of information as the new universal coin of modelling is...http://en.wikipedia.org/wiki/Digital_physics

Well, actually, that is an example of people jumping from epistemology to ontology. They don't just believe physics can be modeled in the standard language of information theory, they claim it actually is just all information!

So this is an illustration of the perils of orthodox reductionism - going overboard in just one direction. But it also shows that the other pole of description exists even at the "lowest level" of material physics.

There is a battle of views going on that is framed dichotomistically - substance vs form, matter vs information.

The strings/TOE debate is another example. Shall we model reality in terms of its fundamental degrees of freedom or its fundamental constraints? The expectation of the TOE camp is that degrees of freedom are infinite, but only one form of constraint (the string theory that works) is actually possible. So then everything (even the fundamental constants, fingers crossed) will be "explained by mathematics".

So again, no quarrel that science is pragmatically formed by a ragged patchwork of modelling domains. But at the same time, the same basic fundamental division infects/unites science at its every level.

Charts can create their own co-ordinates. But generally they are in fact all trying to orientate themselves along the same general compass setting that points north to form/information, and south to sustance/matter.

Neuroscience is just another example. And the best neuroscience - like Grossberg with his plasticity~stability dilemma, or Friston with his Bayesian brain - is focused on finding the appropriate balance between the informational and material view.
 
  • #68
Pythagorean said:
That is a more of a distracting coincidence, I was actually referring to the subjectivity allowed of the investigator to define the partitions of the system himself. The investigator is free to implement a hierarchical approach... and for particular kinds of systems (at least) if we define the partition around the bifurcations of the system, we cannot even avoid adhering to heirarchy (the bifurcation branches) and its relationship to scale (the bifurcation parameter).

Again, you are making my point for me. If it is a subjective work-around, it is not an objective consequence of the model.

Yes, we can get away with doing things simply - either pretending reality is just dynamics, or just computation. We can rely on our informal, subjective, knowledge to avoid misusing models based on those reductionist assumptions.

But that is not the same thing as having a formal basis to a domain of knowledge. It does not address the issue of what is fundamental.

You can then respond, the fundamental doesn't actually matter if we can get by on pragmatics. And again, for some people - many probably - this is indeed enough to satisfy their personal interests.

But for science itself, it does matter. The enterprise of science does have to ensure that all the local domains of modelling connect up objectively - even just pragmatically! - somehow. And a hierarchy of modelling is the way this is being done. Which in turn means extracting the fundamental co-ordinates of this hierarchy (so as to give all the specialised sub-domains some bearings to steer by).
 
  • #69
I think you misunderstand; the point is not to isolate dynamics or computation. The point is that you must already integrate them in the first place. You can do it consciously or you can do it by default (as you hinted at yourself in your reply to atyy).

You can't model everything at once without losing specificity and you can't specify without losing generality. So the investigator has to choose the regime that is appropriate to his question. It's not a "subjective workaround". The subjective part is that the investigator chooses the question to ask, and the partitions can be divided differently for different questions (but all the same underlying system).

From there, you can use any modeling paradigm you wish with the abstracted partitions. For instance, you can treat each partitions as vertices on a graph, and translate dynamical events to the edges connecting the vertices and take a standard connectionist approach.
 
  • #70
Pythagorean said:
I think you misunderstand; the point is not to isolate dynamics or computation.

Sorry, I didn't realize you are probably referring to hidden markov modelling here.

And yes, that would indeed be a hybrid approach because the model acts as an informational constraint on the uncertainty of the world, the dynamical degrees of freedom.

But from dim memory - its been 20 years - HMM approaches are pretty low-powered in practice. And they seemed crude rather than elegant in principle.

If you have references to where they are proving to be now important in theoretical neuroscience, that would be interesting.

It is also a fair point that in any domain of modelling, you need to trade-off generality and specificity. But the question was, what does that look like in neuroscience as a whole, or science as a whole?

And in any case, you are still arguing for a dichotomy in your co-ordinate basis. You are re-stating the fact that there needs to be a compass bearing that points north to generality (global form) and south to specificity (local substance).

Unless you can point out the two complementary directions for your domain of modelling, how do you make any definite specificity~generality trade-off?
 
<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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