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The BCM theory of synaptic plasticity. The BCM theory of cortical plasticity BCM stands for Bienestock Cooper and Munro, it dates back to 1982. It was.

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Presentation on theme: "The BCM theory of synaptic plasticity. The BCM theory of cortical plasticity BCM stands for Bienestock Cooper and Munro, it dates back to 1982. It was."— Presentation transcript:

1 The BCM theory of synaptic plasticity. The BCM theory of cortical plasticity BCM stands for Bienestock Cooper and Munro, it dates back to 1982. It was designed in order to account for experiments which demonstrated that the development of orientation selective cells depends on rearing in a patterned environment.

2 BCM Theory (Bienenstock, Cooper, Munro 1982; Intrator, Cooper 1992) Bidirectional synaptic modification LTP/LTD Sliding modification threshold The fixed points depend on the environment, and in a patterned environment only selective fixed points are stable. LTD LTP Requires

3 Is equivalent to this differential form: The integral form of the average: Note, it is essential that θ m is a superlinear function of the history of C, that is: with p>0 Note also that in the original BCM formulation (1982) rather then

4 What is the outcome of the BCM theory? Assume a neuron with N inputs (N synapses), and an environment composed of N different input vectors. A N=2 example: What are the stable fixed points of W in this case? x1x1 x2x2

5 (Notation: ) What are the fixed points? What are the stable fixed points? Note: Every time a new input is presented, m changes, and so does θ m x1x1 x2x2

6 Two examples with N= 5 Note: The stable FP is such that for one pattern y i =w T x i =θ m while for the others y (i≠j) =0. (note: here c=y) Show movie

7 BCM Theory Stability One dimension Quadratic form Instantaneous limit

8 BCM Theory Selectivity Two dimensions Two patterns Quadratic form Averaged threshold, Fixed points

9 BCM Theory: Selectivity Learning Equation Four possible fixed points,,,, (unselective) (Selective) Threshold

10 Consider a selective F.P (w 1 ) where: and So that for a small pertubation from the F.P such that The two inputs result in: So that

11 At y≈0 and at y≈θ m we make a linear approximation In order to examine whether a fixed point is stable we examine if the average norm of the perturbation ||Δw|| increases or decreases. Decrease ≡ Stable Increase ≡ Unstable

12 Note: for a small perturbation θ m changes such that: For the preferred input x 1 : (show form here up to end of proof + bonus 50 pt) For the non preferred input x 2

13 Note: for a small perturbation θ m changes such that: For the preferred input x 1 : (show from here up to end of proof + bonus 25 pt) For the non preferred input x 2 (Note O(Δw 2 ) is very small)

14 Use trick: And Insert previous to show that:

15 Phase plane analysis of BCM in 1D Previous analysis assumed that θ m =E[y 2 ] exactly. If we use instead the dynamical equation Will the stability be altered? Look at 1D example

16 Phase plane analysis of BCM in 1D Assume x=1 and therefore y=w. Get the two BCM equations: There are two fixed points y=0, θ m =0, and y=1, θ m =1. The previous analysis shows that the second one is stable, what would be the case here? How can we do this? (supplementary homework problem) 0 0.5 1 θ m y 1 0.5 0 ?

17 Linear stability analysis:

18 Summary The BCM rule is based on two differential equations, what are they? When there are two linearly independent inputs, what will be the BCM stable fixed points? What will θ be? When there are K independent inputs, what are the stable fixed points? What will θ be?

19 Homework 2: due in 10 days 1.Code a single BCM neuron, apply to case with 2 linearly independent inputs with equal probability 2. Apply to 2 inputs with different probabilities, what is different? 3. Apply to 4 linearly indep. Inputs with same prob. Extra credit 25 pt 4. a. Analyze the f.p in 1D case, what are the stable f.p as a function of the systems parameters. b. Use simulations to plot dynamics of y(t), θ(t) and their trajectories in the m θ plane for different parameters. Compare stability to analytical results (Key parameters, η τ)

20 Natural Images, Noise, and Learning image retinal activity present patches update weights Patches from retinal activity image Patches from noise Retina LGN Cortex

21 Resulting receptive fields Corresponding tuning curves

22 BCM neurons can develop both orientation selectivity and varying degrees of Ocular Dominance Shouval et. al., Neural Computation, 1996 Left Eye Right Eye Right Synapses Left Synapses

23 Monocular Deprivation Homosynaptic model (BCM) High noise Low noise

24 Monocular Deprivation Heterosynaptic model (K2) High noise Low noise

25 Noise Dependence of MD Two families of synaptic plasticity rules Homosynaptic Heterosynaptic Blais, Shouval, Cooper. PNAS, 1999 QBCM K1K1 S1S1 Noise std S2S2 K2K2 PCA Noise std Normalized Time

26 Lid closed Time (sec) Right Retina LGN TTX

27 Experiment design Blind injection of TTX and lid- suture (P49-61) Dark rearing to allow TTX to wear off Quantitative measurements of ocular dominance

28 Response rate (spikes/sec)

29 Rittenhouse, Shouval, Paradiso, Bear - Nature 1999 MS= Monocular lid suture MI= Monocular inactivation (TTX) Cumulative distribution Of OD

30 Why is Binocular Deprivation slower than Monocular Deprivation? Monocular DeprivationBinocular Deprivation

31 What did we learn up to here?

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