add learn()

2023-07-26 15:21:34 +07:00
parent ff9909fd8d
commit a94354efb3
6 changed files with 224 additions and 87 deletions
--- a/Manifest.toml
+++ b/Manifest.toml
@@ -2,7 +2,7 @@
 julia_version = "1.9.2"
 manifest_format = "2.0"
-project_hash = "1a1cddac46fdd2108611b4e2f350497572f0c8d4"
+project_hash = "1d38b0278f78d536c218e3a421dfd88a68063099"
 [[deps.AbstractFFTs]]
 deps = ["LinearAlgebra"]
--- a/Project.toml
+++ b/Project.toml
@@ -5,6 +5,10 @@ version = "0.1.0"
 [deps]
 CUDA = "052768ef-5323-5732-b1bb-66c8b64840ba"
 Dates = "ade2ca70-3891-5945-98fb-dc099432e06a"
 Flux = "587475ba-b771-5e3f-ad9e-33799f191a9c"
 GeneralUtils = "c6c72f09-b708-4ac8-ac7c-2084d70108fe"
 JSON3 = "0f8b85d8-7281-11e9-16c2-39a750bddbf1"
 LinearAlgebra = "37e2e46d-f89d-539d-b4ee-838fcccc9c8e"
 Random = "9a3f8284-a2c9-5f02-9a11-845980a1fd5c"
 Statistics = "10745b16-79ce-11e8-11f9-7d13ad32a3b2"
--- a/src/IronpenGPU.jl
+++ b/src/IronpenGPU.jl
@@ -1,4 +1,4 @@
-module IronpenGPU
+module IronpenGPU   # this is a parent module
 # export 
@@ -8,7 +8,7 @@ files and each file can only depend on the file included before it.
 """
 include("type.jl")
-using .type    # bring model into this module namespace (this module is a parent module)
+using .type    # bring type into parent module namespace 
 include("snnUtil.jl")
 using .snnUtil
--- a/src/forward.jl
+++ b/src/forward.jl
@@ -18,16 +18,16 @@ function (kfn::kfn_1)(input::AbstractArray)
        # reset learning params
    end
    println(">>> input ", size(input))
    d1, d2, d3 = size(input)
-    println(">>> zit ", size(kfn.zit)) 
+    # println(">>> input ", size(input))
-    println(">>> lif_zit ", size(kfn.lif_zit)) 
+    # println(">>> zit ", size(kfn.zit)) 
    # println(">>> lif_zit ", size(kfn.lif_zit)) 
    # println(">>> lif_recSignal ", size(kfn.lif_recSignal))
-    println(">>> lif_wRec ", size(kfn.lif_wRec))
+    # println(">>> lif_wRec ", size(kfn.lif_wRec))
-    println(">>> lif_refractoryCounter ", size(kfn.lif_refractoryCounter))
+    # println(">>> lif_refractoryCounter ", size(kfn.lif_refractoryCounter))
-    println(">>> lif_alpha ", size(kfn.lif_alpha))
+    # println(">>> lif_alpha ", size(kfn.lif_alpha))
-    println(">>> lif_vt0 ", size(kfn.lif_vt0))
+    # println(">>> lif_vt0 ", size(kfn.lif_vt0))
-    println(">>> lif_vt0 sum ", sum(kfn.lif_vt0))
+    # println(">>> lif_vt0 sum ", sum(kfn.lif_vt0))
    # pass input_data into input neuron.
    GeneralUtils.cartesianAssign!(kfn.zit, input)
@@ -45,7 +45,8 @@ function (kfn::kfn_1)(input::AbstractArray)
                kfn.lif_epsilonRec,
                kfn.lif_refractoryCounter,
                kfn.lif_refractoryDuration,
-                kfn.lif_gammaPd)
+                kfn.lif_gammaPd,
                kfn.lif_firingCounter)
    alifForward( kfn.zit, 
                 kfn.alif_zit,
@@ -65,7 +66,8 @@ function (kfn::kfn_1)(input::AbstractArray)
                 kfn.alif_a,
                 kfn.alif_beta,
                 kfn.alif_rho,
-                 kfn.alif_gammaPd)
+                 kfn.alif_gammaPd,
                 kfn.alif_firingCounter)
    # update activation matrix by concatenate (input, lif_zt1, alif_zt1) to form activation matrix
    _zit = cat(reshape(input, (d1, d2, 1, d3)), 
@@ -76,7 +78,7 @@ function (kfn::kfn_1)(input::AbstractArray)
    # read out
    onForward( kfn.zit, 
                kfn.on_zit,
-                kfn.on_wRec, 
+                kfn.on_wOut, 
                kfn.on_vt0, 
                kfn.on_vt1,
                kfn.on_vth,
@@ -87,9 +89,11 @@ function (kfn::kfn_1)(input::AbstractArray)
                kfn.on_epsilonRec,
                kfn.on_refractoryCounter,
                kfn.on_refractoryDuration,
-                kfn.on_gammaPd)
+                kfn.on_gammaPd,
                kfn.on_firingCounter)
-    return kfn.on_zt1
+    return reshape(kfn.on_zt1, (d1, :)),
            kfn.zit
 end
 function lifForward(kfn_zit, 
@@ -105,7 +109,8 @@ function lifForward(kfn_zit,
                    epsilonRec,
                    refractoryCounter,
                    refractoryDuration,
-                    gammaPd)
+                    gammaPd,
                    firingCounter)
    d1, d2, d3, d4 = size(wRec)
    zit .= reshape(kfn_zit, (d1, d2, 1, d4)) .* ones(size(wRec)...)   # project zit into zit
@@ -161,7 +166,8 @@ function alifForward(kfn_zit,
                    a,
                    beta,
                    rho,
-                    gammaPd)
+                    gammaPd,
                    firingCounter)
    d1, d2, d3, d4 = size(wRec)
    zit .= reshape(kfn_zit, (d1, d2, 1, d4)) .* ones(size(wRec)...)   # project zit into zit
@@ -215,7 +221,7 @@ end
 function onForward(kfn_zit, 
                    zit,
-                    wRec, 
+                    wOut, 
                    vt0, 
                    vt1,
                    vth,
@@ -226,9 +232,10 @@ function onForward(kfn_zit,
                    epsilonRec,
                    refractoryCounter,
                    refractoryDuration,
-                    gammaPd)
+                    gammaPd,
-    d1, d2, d3, d4 = size(wRec)
+                    firingCounter)
-    zit .= reshape(kfn_zit, (d1, d2, 1, d4)) .* ones(size(wRec)...)   # project zit into zit
+    d1, d2, d3, d4 = size(wOut)
    zit .= reshape(kfn_zit, (d1, d2, 1, d4)) .* ones(size(wOut)...)   # project zit into zit
    for j in 1:d4, i in 1:d3    # compute along neurons axis of every batch
        if view(refractoryCounter, :, :, i, j)[1] > 0   # neuron is inactive (in refractory period)
@@ -242,7 +249,7 @@ function onForward(kfn_zit,
        else    # neuron is active
            view(vt1, :, :, i, j)[1] = 
                                (view(alpha, :, :, i, j)[1] * view(vt0,:, :, i, j)[1]) + 
-                                sum(view(zit, :, :, i, j) .* view(wRec, :, :, i, j))
+                                sum(view(zit, :, :, i, j) .* view(wOut, :, :, i, j))
            if view(vt1, :, :, i, j)[1] > view(vth, :, :, i, j)[1]
                view(zt1, :, :, i, j)[1] = 1
                view(refractoryCounter, :, :, i, j)[1] = 
--- a/src/learn.jl
+++ b/src/learn.jl
@@ -1,16 +1,131 @@
 module learn
-# export
+export learn!, compute_paramsChange!
-# using
+using Statistics, Random, LinearAlgebra, JSON3, Flux, Dates
 using GeneralUtils
 using ..type, ..snnUtil
 #------------------------------------------------------------------------------------------------100
 function compute_paramsChange!(kfn::kfn_1, modelError, outputError)
    #WORKING
    lifComputeParamsChange!(kfn.lif_phi, 
                            kfn.lif_epsilonRec, 
                            kfn.lif_eta, 
                            kfn.lif_wRec,
                            kfn.lif_wRecChange, 
                            kfn.on_wOut, 
                            modelError)
    alifComputeParamsChange!(kfn.alif_phi, 
                             kfn.alif_epsilonRec, 
                             kfn.alif_epsilonRecA,
                             kfn.alif_eta, 
                             kfn.alif_wRec,
                             kfn.alif_wRecChange, 
                             kfn.alif_beta, 
                             kfn.on_wOut, 
                             modelError)
    error("debug end    ->  kfn compute_paramsChange!    $(Dates.now())") 
    # Threads.@threads for n in kfn.neuronsArray
    #     # for n in kfn.neuronsArray
    #     if typeof(n) <: computeNeuron
    #         wOut = Int64[]
    #         for oN in kfn.outputNeuronsArray
    #             wIndex = findall(isequal.(oN.subscriptionList, n.id))
    #             if length(wIndex) != 0
    #                 push!(wOut, wIndex[1])
    #             end
    #         end
    #         if length(wOut) != 0
    #             compute_wRecChange!(n, wOut, modelError)
    #             # compute_alphaChange!(n, modelError)
    #             compute_firingRateError!(n, kfn.kfnParams[:neuronFiringRateTarget], 
    #                                     kfn.kfnParams[:totalComputeNeuron])
    #         end
    #     end
    # end
    #  for oN in kfn.outputNeuronsArray
    #     compute_wRecChange!(oN, outputError[oN.id])
    #     # compute_alphaChaZnge!(oN, outputError[oN.id])
    # end
 end
 function lifComputeParamsChange!(   phi, 
                                    epsilonRec, 
                                    eta, 
                                    wRec,
                                    wRecChange, 
                                    wOut, 
                                    modelError)
    d1, d2, d3, d4 = size(epsilonRec)
    # Bₖⱼ in paper, sum() to get each neuron's total wOut weight 
    wOutSum = reshape(sum(wOut, dims=3), (d1, :, d4))
    for j in 1:d4, i in 1:d3    # compute along neurons axis of every batch
        # how much error of this neuron 1-spike causing each output neuron's error
        view(wRecChange, :, :, i, j) .+= (-1 * view(eta, :, :, i, j)[1]) .* 
                # eRec
                ( (view(phi, :, :, i, j)[1] .* view(epsilonRec, :, :, i, j)) .*       
                    # nError a.k.a. learning signal
                    (view(modelError, :, j)[1] .* 
                        # RSNN neuron's total wOut weight (neuron synaptic subscription .* wOutSum)
                        sum(GeneralUtils.isNotEqual.(view(wRec, :, :, i, j), 0) .* 
                            view(wOutSum, :, :, j))
                    ) 
                )
    end
 end
 function alifComputeParamsChange!(  phi, 
                                    epsilonRec,
                                    epsilonRecA,
                                    eta, 
                                    wRec,
                                    wRecChange, 
                                    beta,
                                    wOut, 
                                    modelError)
    d1, d2, d3, d4 = size(epsilonRec)
    # Bₖⱼ in paper, sum() to get each neuron's total wOut weight 
    wOutSum = reshape(sum(wOut, dims=3), (d1, :, d4))
    for j in 1:d4, i in 1:d3    # compute along neurons axis of every batch
        # how much error of this neuron 1-spike causing each output neuron's error
        view(wRecChange, :, :, i, j) .+= (-1 * view(eta, :, :, i, j)[1]) .* 
                # eRec
                ( 
                    # eRec_v
                    (view(phi, :, :, i, j)[1] .* view(epsilonRec, :, :, i, j)) .+
                    # eRec_a
                    ((view(phi, :, :, i, j)[1] * view(beta, :, :, i, j)[1]) .* 
                        view(epsilonRecA, :, :, i, j))
                ) .* 
                # nError a.k.a. learning signal
                (
                    view(modelError, :, j)[1] .* 
                    # RSNN neuron's total wOut weight (neuron synaptic subscription .* wOutSum)
                    sum(GeneralUtils.isNotEqual.(view(wRec, :, :, i, j), 0) .* 
                        view(wOutSum, :, :, j))
                ) 
    end
 end
--- a/src/type.jl
+++ b/src/type.jl
@@ -43,8 +43,10 @@ Base.@kwdef mutable struct kfn_1 <: knowledgeFn
    lif_tau_m::AbstractFloat = 20.0
    lif_phi::Union{AbstractArray, Nothing} = nothing
    lif_epsilonRec::Union{AbstractArray, Nothing} = nothing
    # lif_eRec::Union{AbstractArray, Nothing} = nothing
    lif_eta::Union{AbstractArray, Nothing} = nothing
    lif_gammaPd::Union{AbstractArray, Nothing} = nothing
    lif_wRecChange::Union{AbstractArray, Nothing} = nothing
    lif_firingCounter::Union{AbstractArray, Nothing} = nothing
@@ -69,8 +71,10 @@ Base.@kwdef mutable struct kfn_1 <: knowledgeFn
    alif_phi::Union{AbstractArray, Nothing} = nothing
    alif_epsilonRec::Union{AbstractArray, Nothing} = nothing
    alif_epsilonRecA::Union{AbstractArray, Nothing} = nothing
    # alif_eRec::Union{AbstractArray, Nothing} = nothing
    alif_eta::Union{AbstractArray, Nothing} = nothing
    alif_gammaPd::Union{AbstractArray, Nothing} = nothing
    alif_wRecChange::Union{AbstractArray, Nothing} = nothing
    alif_firingCounter::Union{AbstractArray, Nothing} = nothing
@@ -85,7 +89,7 @@ Base.@kwdef mutable struct kfn_1 <: knowledgeFn
    # output neuron is based on LIF
    on_zit::Union{AbstractArray, Nothing} = nothing  
-    on_wRec::Union{AbstractArray, Nothing} = nothing
+    on_wOut::Union{AbstractArray, Nothing} = nothing    # same as lif_wRec
    on_vt0::Union{AbstractArray, Nothing} = nothing
    on_vt1::Union{AbstractArray, Nothing} = nothing
    on_vth::Union{AbstractArray, Nothing} = nothing
@@ -99,8 +103,10 @@ Base.@kwdef mutable struct kfn_1 <: knowledgeFn
    on_tau_m::AbstractFloat = 20.0
    on_phi::Union{AbstractArray, Nothing} = nothing
    on_epsilonRec::Union{AbstractArray, Nothing} = nothing
    on_eRec::Union{AbstractArray, Nothing} = nothing
    on_eta::Union{AbstractArray, Nothing} = nothing
    on_gammaPd::Union{AbstractArray, Nothing} = nothing
    on_wOutChange::Union{AbstractArray, Nothing} = nothing
    on_firingCounter::Union{AbstractArray, Nothing} = nothing
 end
@@ -128,24 +134,26 @@ function kfn_1(params::Dict)
    # ---------------------------------------------------------------------------- #
    # In 3D LIF matrix, z-axis represent each neuron while each 2D slice represent that neuron's 
    # synaptic subscription to other neurons (via activation matrix)
-    z = kfn.params[:computeNeuron][:lif][:numbers][1] * kfn.params[:computeNeuron][:lif][:numbers][2]
+    n = kfn.params[:computeNeuron][:lif][:numbers][1] * kfn.params[:computeNeuron][:lif][:numbers][2]
-    kfn.lif_zit = zeros(row, col, z, batch)
+    kfn.lif_zit = zeros(row, col, n, batch)
-    kfn.lif_vt0 = zeros(1, 1, z, batch)
+    kfn.lif_vt0 = zeros(1, 1, n, batch)
-    kfn.lif_vt1 = zeros(1, 1, z, batch)
+    kfn.lif_vt1 = zeros(1, 1, n, batch)
-    kfn.lif_vth = ones(1, 1, z, batch)
+    kfn.lif_vth = ones(1, 1, n, batch)
-    kfn.lif_vRest = zeros(1, 1, z, batch)
+    kfn.lif_vRest = zeros(1, 1, n, batch)
-    kfn.lif_zt0 = zeros(1, 1, z, batch)
+    kfn.lif_zt0 = zeros(1, 1, n, batch)
-    kfn.lif_zt1 = zeros(1, 1, z, batch)
+    kfn.lif_zt1 = zeros(1, 1, n, batch)
-    kfn.lif_refractoryCounter = zeros(1, 1, z, batch)
+    kfn.lif_refractoryCounter = zeros(1, 1, n, batch)
-    kfn.lif_refractoryDuration = ones(1, 1, z, batch) .* 3
+    kfn.lif_refractoryDuration = ones(1, 1, n, batch) .* 3
-    kfn.lif_alpha = ones(1, 1, z, batch) .* (exp(-kfn.lif_delta / kfn.lif_tau_m))
+    kfn.lif_alpha = ones(1, 1, n, batch) .* (exp(-kfn.lif_delta / kfn.lif_tau_m))
-    kfn.lif_phi = zeros(1, 1, z, batch)
+    kfn.lif_phi = zeros(1, 1, n, batch)
-    kfn.lif_epsilonRec = zeros(row, col, z, batch)
+    kfn.lif_epsilonRec = zeros(row, col, n, batch)
-    kfn.lif_eta = zeros(1, 1, z, batch)
+    # kfn.lif_eRec = zeros(row, col, n, batch)
-    kfn.lif_gammaPd = zeros(1, 1, z, batch) .* 0.3
+    kfn.lif_eta = zeros(1, 1, n, batch)
    kfn.lif_gammaPd = zeros(1, 1, n, batch) .* 0.3
    kfn.lif_wRecChange = zeros(row, col, n, batch)
    # subscription
-    w = zeros(row, col, z)
+    w = zeros(row, col, n)
    synapticConnectionPercent = kfn.params[:computeNeuron][:lif][:params][:synapticConnectionPercent]
    synapticConnection = Int(floor(row*col * synapticConnectionPercent/100))
    for slice in eachslice(w, dims=3)
@@ -155,36 +163,38 @@ function kfn_1(params::Dict)
        end
    end
    # project 3D w into 4D kfn.lif_wRec
-    kfn.lif_wRec = reshape(w, (row, col, z, 1)) .* ones(row, col, z, batch)
+    kfn.lif_wRec = reshape(w, (row, col, n, 1)) .* ones(row, col, n, batch)
-    kfn.lif_firingCounter = zeros(1, 1, z, batch)
+    kfn.lif_firingCounter = zeros(1, 1, n, batch)
    # ---------------------------------------------------------------------------- #
    #                                  ALIF config                                 #
    # ---------------------------------------------------------------------------- #
-    z = kfn.params[:computeNeuron][:alif][:numbers][1] * kfn.params[:computeNeuron][:alif][:numbers][2]
+    n = kfn.params[:computeNeuron][:alif][:numbers][1] * kfn.params[:computeNeuron][:alif][:numbers][2]
-    kfn.alif_zit = zeros(row, col, z, batch)
+    kfn.alif_zit = zeros(row, col, n, batch)
-    kfn.alif_vt0 = zeros(1, 1, z, batch)
+    kfn.alif_vt0 = zeros(1, 1, n, batch)
-    kfn.alif_vt1 = zeros(1, 1, z, batch)
+    kfn.alif_vt1 = zeros(1, 1, n, batch)
-    kfn.alif_vth = ones(1, 1, z, batch)
+    kfn.alif_vth = ones(1, 1, n, batch)
-    kfn.alif_avth = ones(1, 1, z, batch)
+    kfn.alif_avth = ones(1, 1, n, batch)
-    kfn.alif_vRest = zeros(1, 1, z, batch)
+    kfn.alif_vRest = zeros(1, 1, n, batch)
-    kfn.alif_zt0 = zeros(1, 1, z, batch)
+    kfn.alif_zt0 = zeros(1, 1, n, batch)
-    kfn.alif_zt1 = zeros(1, 1, z, batch)
+    kfn.alif_zt1 = zeros(1, 1, n, batch)
-    kfn.alif_refractoryCounter = zeros(1, 1, z, batch)
+    kfn.alif_refractoryCounter = zeros(1, 1, n, batch)
-    kfn.alif_refractoryDuration = ones(1, 1, z, batch) .* 3
+    kfn.alif_refractoryDuration = ones(1, 1, n, batch) .* 3
-    kfn.alif_alpha = ones(1, 1, z, batch) .* (exp(-kfn.alif_delta / kfn.alif_tau_m))
+    kfn.alif_alpha = ones(1, 1, n, batch) .* (exp(-kfn.alif_delta / kfn.alif_tau_m))
-    kfn.alif_phi = zeros(1, 1, z, batch)
+    kfn.alif_phi = zeros(1, 1, n, batch)
-    kfn.alif_epsilonRec = zeros(row, col, z, batch)
+    kfn.alif_epsilonRec = zeros(row, col, n, batch)
-    kfn.alif_epsilonRecA = zeros(row, col, z, batch)
+    kfn.alif_epsilonRecA = zeros(row, col, n, batch)
-    kfn.alif_eta = zeros(1, 1, z, batch)
+    # kfn.alif_eRec = zeros(row, col, n, batch)
-    kfn.alif_gammaPd = zeros(1, 1, z, batch) .* 0.3
+    kfn.alif_eta = zeros(1, 1, n, batch)
    kfn.alif_gammaPd = zeros(1, 1, n, batch) .* 0.3
    kfn.alif_wRecChange = zeros(row, col, n, batch)
-    kfn.alif_a = zeros(1, 1, z, batch)
+    kfn.alif_a = zeros(1, 1, n, batch)
-    kfn.alif_beta = zeros(1, 1, z, batch) .* 0.15
+    kfn.alif_beta = zeros(1, 1, n, batch) .* 0.15
-    kfn.alif_rho = zeros(1, 1, z, batch) .* (exp(-kfn.alif_delta / kfn.alif_tau_a))
+    kfn.alif_rho = zeros(1, 1, n, batch) .* (exp(-kfn.alif_delta / kfn.alif_tau_a))
    # subscription
-    w = zeros(row, col, z)
+    w = zeros(row, col, n)
    synapticConnectionPercent = kfn.params[:computeNeuron][:alif][:params][:synapticConnectionPercent]
    synapticConnection = Int(floor(row*col * synapticConnectionPercent/100))
    for slice in eachslice(w, dims=3)
@@ -194,31 +204,32 @@ function kfn_1(params::Dict)
        end
    end
    # project 3D w into 4D kfn.alif_wRec
-    kfn.alif_wRec = reshape(w, (row, col, z, 1)) .* ones(row, col, z, batch)
+    kfn.alif_wRec = reshape(w, (row, col, n, 1)) .* ones(row, col, n, batch)
-    kfn.alif_firingCounter = zeros(1, 1, z, batch)
+    kfn.alif_firingCounter = zeros(1, 1, n, batch)
    # ---------------------------------------------------------------------------- #
    #                                 output config                                #
    # ---------------------------------------------------------------------------- #
-    #WORKING
+    n = kfn.params[:outputPort][:numbers][1] * kfn.params[:outputPort][:numbers][2]
-    z = kfn.params[:outputPort][:numbers][1] * kfn.params[:outputPort][:numbers][2]
+    kfn.on_zit = zeros(row, col, n, batch)
-    kfn.on_zit = zeros(row, col, z, batch)
+    kfn.on_vt0 = zeros(1, 1, n, batch)
-    kfn.on_vt0 = zeros(1, 1, z, batch)
+    kfn.on_vt1 = zeros(1, 1, n, batch)
-    kfn.on_vt1 = zeros(1, 1, z, batch)
+    kfn.on_vth = ones(1, 1, n, batch)
-    kfn.on_vth = ones(1, 1, z, batch)
+    kfn.on_vRest = zeros(1, 1, n, batch)
-    kfn.on_vRest = zeros(1, 1, z, batch)
+    kfn.on_zt0 = zeros(1, 1, n, batch)
-    kfn.on_zt0 = zeros(1, 1, z, batch)
+    kfn.on_zt1 = zeros(1, 1, n, batch)
-    kfn.on_zt1 = zeros(1, 1, z, batch)
+    kfn.on_refractoryCounter = zeros(1, 1, n, batch)
-    kfn.on_refractoryCounter = zeros(1, 1, z, batch)
+    kfn.on_refractoryDuration = ones(1, 1, n, batch) .* 1
-    kfn.on_refractoryDuration = ones(1, 1, z, batch) .* 1
+    kfn.on_alpha = ones(1, 1, n, batch) .* (exp(-kfn.on_delta / kfn.on_tau_m))
-    kfn.on_alpha = ones(1, 1, z, batch) .* (exp(-kfn.on_delta / kfn.on_tau_m))
+    kfn.on_phi = zeros(1, 1, n, batch)
-    kfn.on_phi = zeros(1, 1, z, batch)
+    kfn.on_epsilonRec = zeros(row, col, n, batch)
-    kfn.on_epsilonRec = zeros(row, col, z, batch)
+    # kfn.on_eRec = zeros(row, col, n, batch)
-    kfn.on_eta = zeros(1, 1, z, batch)
+    kfn.on_eta = zeros(1, 1, n, batch)
-    kfn.on_gammaPd = zeros(1, 1, z, batch) .* 0.3
+    kfn.on_gammaPd = zeros(1, 1, n, batch) .* 0.3
    kfn.on_wOutChange = zeros(row, col, n, batch)
    # subscription
-    w = zeros(row, col, z)
+    w = zeros(row, col, n)
    synapticConnectionPercent = kfn.params[:outputPort][:params][:synapticConnectionPercent]
    synapticConnection = Int(floor(row*col * synapticConnectionPercent/100))
    for slice in eachslice(w, dims=3)
@@ -227,9 +238,9 @@ function kfn_1(params::Dict)
            slice[i] = randn()/10   # assign weight to synaptic connection
        end
    end
-    # project 3D w into 4D kfn.on_wRec
+    # project 3D w into 4D kfn.on_wOut
-    kfn.on_wRec = reshape(w, (row, col, z, 1)) .* ones(row, col, z, batch)
+    kfn.on_wOut = reshape(w, (row, col, n, 1)) .* ones(row, col, n, batch)
-    kfn.on_firingCounter = zeros(1, 1, z, batch)
+    kfn.on_firingCounter = zeros(1, 1, n, batch)