Howell: priority NN projects

Table of Contents

• Introduction
• callerID-SNNs
  • [why, how] does a neuron spike? (or not) :
  • Advantages, characteristics :
  • Disadvantages :
• Mechanisms for processing [DNA, RNA] 'program code'
• MindCode: Genetics and NNs
• Stephen Grossberg 2021 'Conscious Mind, Resonant Brain'

Introduction

• overall image of themes supporting each other

callerID-SNNs

[why, how] does a neuron spike? (or not)

• membrane potential threshold is the conventional spike-driving mechanism that is assumed.
• the "callerID" approach would also provide a basis for assuming that a neuron will fire when incoming spike trains confirm a firing condition based on multiple input neurons, rather than only when a threshold potential is reached.

Advantages, characteristics

• simple bit-shifts can do a lot of the initial work for spiking time series
• implements one speculative function (filtering of spike streams) for dendritic trees. I have not yet focussed on other possible functions, as provided by literature.
• noise reduction in addition to identifying the "callerID" neuron that has sent a specific spike train, independent of the type type of spiking, for example : Itzhikevich's [regular (RS), instrinsically bursting (IB), chattering (CH), fast spiking (FS), thalomo-cortical (TC), resonator (RZ), low-threshold spiking (LTS)] Izhikevich Nov2003 Known types of neurons
• No gradient is used for a "pure" application of "callerID-SNNs" for [filtering, neuronID].
• Rather than calculate spiking in "longer-than-synaptic-blurb" timescales, simple binning is being considered. Other thought will come later, but likely only after resolving challenges of
• May help to explain one of the functions of "bushy" axonal trees?
• possible reduction of the computational load of training SNNs (downstream of CallerID-SNNs)
• more [reliable, robust, time-precise, source-neuron-specific] identification of incoming spike sequences would be a huge opportunity for using the spikes for "downstream" [calculation, model]s, such as [number representation, arithmetic, function approximation, calculus].

• video of multiple input neuron (neurInn) spike trains + variable noise + sudden noise -> "Post-Synaptic Blurb" (PSB) streams for each neurInn -> combined PSB stream -> filtering -> neurInn(i, t_start) -> back to video start point
• de-convoluted noise, potential for learning [new, changed, damaged] input neurons

Disadvantages

• genetic-based approaches for driving neuron spikes are not an accepted concept, and its biological plausibility has not been established. This makes it a no-go for [math, science, engineer] professionals, maybe not essentially all of them, but at least almost all. Overall, standards of practice based on years of applications expereience make things safer for us all.
• Spike filtering would occur at timescales 10-100 time faster than higher level SNN [intra, extra]-cellular processs. Normal [genetic, neuron] processes may be far too low for what is required?
• Learning by "callerID-SNNs" has not yet been addressed. The intent is to look into a combination of :
  • genetic mechanisms within-the-neuron (intra-cellular), as well as interactions between neurons (extra-cellular)
  • conventional gradient descent, and [evolutionary computation, particle swarm, etc] non-gradient methods
  • Grossberg's concepts for [neuron, [micro, macro]-circuit]s. Grossberg also discusses [intr, extra]-cellular process, and are obvious concepts as tie-ins to [DNA, RNA] (evolutionary) coding?
  When used with the standard SNN models, gradients would normally be required.

Tuning instead of training

• Gradients are normally required for training, but for now I am simply assuming that I will start with SNN gradient methods, rather than converting [Deep Learning [CNN, TrNN], other continuous NN] to SNN.
• "callerID-SNNs" has not yet been addressed in any depth. The intent is to look into a combination of :
  • genetic mechanisms within-the-neuron (intra-cellular), as well as interactions between neurons (extra-cellular)
  • conventional gradient descent, and [evolutionary computation, particle swarm, etc] non-gradient methods
  • Grossberg's concepts for [neuron, [micro, macro]-circuit]s. Grossberg also discusses [intr, extra]-cellular process, and are obvious concepts as tie-ins to [DNA, RNA] (evolutionary) coding?
  • [number representation, arithmetic, function approximation, calculus] are subjects for later consideration.
  When used with the standard SNN models, gradients would normally be required.

Mechanisms for processing [DNA, RNA] 'program code'

• electro-mechanical [real, biological] mechanisms for "transporting" bio-chemical material around (eg microtubules etc)
• [gel, bulk] water phase changes
• most importantly right now - mechanisms for coprocessing multiple mRNA strands

• DNA -> tRNA -> mRNA
  -> [protein, program] code
  |---> protein image
  |---> program code image

MindCode: Genetics and NNs

• non-protein coding parts of the DNA - searching for coding-like polypeptice "keywords" equivalent to various classical programming [copy, remove, assignment, control [if, while, done, etc].
• the [role, processes of] of [program, protein] coding in [DNA, RNA] - if program coding exists (I assume it must in some form). Bilogical research since ?I don't know when?, and Deep Learning research since ~2020? is generating "interactions" between protein and non-coding mRNA that may be a good starting point?

• somehow show Mindcode program tying to Grossberg's ART