2023-12-22 16:39:03 +00:00
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---
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tags:
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- ai
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---
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2023-06-07 09:02:27 +01:00
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*Time-dependent, highly local, strongly interactive*
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- Oldest learning algorithm
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- Increases synaptic efficiency as a function of the correlation between presynaptic and postsynaptic activities
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1. If two neurons on either side of a synapse are activated simultaneously/synchronously, then the strength of that synapse is selectively increased
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2. If two neurons on either side of a synapse are activated asynchronously, then that synapse is selectively weakened or eliminated
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- Hebbian synapse
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- Time-dependent
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- Depends on times of pre/post-synaptic signals
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- Local
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- Interactive
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- Depends on both sides of synapse
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- True interaction between pre/post-synaptic signals
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- Cannot make prediction from either one by itself
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- Conjunctional or correlational
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- Based on conjunction of pre/post-synaptic signals
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- Conjunctional synapse
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- Modification classifications
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- Hebbian
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- **Increases** strength with **positively** correlated pre/post-synaptic signals
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- **Decreases** strength with **negatively** correlated pre/post-synaptic signals
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- Anti-Hebbian
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- **Decreases** strength with **positively** correlated pre/post-synaptic signals
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- **Increases** strength with **negatively** correlated pre/post-synaptic signals
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- Still Hebbian in nature, not in function
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- Non-Hebbian
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- Doesn't involve above correlations/time dependence etc
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# Mathematically
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$$\Delta w_{kj}(n)=F\left(y_k(n),x_j(n)\right)$$
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- Generally
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- All Hebbian
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![](../../../img/hebb-learning.png)
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## Hebb's Hypothesis
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$$\Delta w_{kj}(n)=\eta y_k(n)x_j(n)$$
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- Activity product rule
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- Exponential growth until saturation
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- No information stored
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- Selectivity lost
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## Covariance Hypothesis
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$$\Delta w_{kj}(n)=\eta(x_j-\bar x)(y_k-\bar y)$$
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- Characterised by perturbation from of pre/post-synaptic signals from their mean over a given time interval
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- Average $x$ and $y$ constitute thresholds
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- Intercept at y = y bar
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- Similar to learning in the hippocampus
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*Allows:*
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1. Convergence to non-trivial state
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- When x = x bar or y = y bar
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2. Prediction of both synaptic potentiation and synaptic depression
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