From 8bf94c6900db2fe03076363d9d3d002ba8a9bbaa Mon Sep 17 00:00:00 2001 From: "F.M. Quintana Velazquez" Date: Fri, 27 Feb 2026 17:55:57 +0100 Subject: [PATCH] Deployed 9fabbde with MkDocs version: 1.6.1 --- neuron_models/lif/index.html | 2 +- {img => neuron_models/lif}/lif_plot.png | Bin {img => neuron_models/snowball}/exif_plot.png | Bin neuron_models/snowball/index.html | 2 +- print_page/index.html | 2 +- 5 files changed, 3 insertions(+), 3 deletions(-) rename {img => neuron_models/lif}/lif_plot.png (100%) rename {img => neuron_models/snowball}/exif_plot.png (100%) diff --git a/neuron_models/lif/index.html b/neuron_models/lif/index.html index 81ad91f..742c6d2 100644 --- a/neuron_models/lif/index.html +++ b/neuron_models/lif/index.html @@ -813,7 +813,7 @@

Circuit Design

W/L = 4/3

Circuit Simulation

-

lif, output plot Fig.1 The dynamics of leaky integrate and fire neuron. The grey signal is the input spikes, the yellow signal is the membrane potential and the dark blue is the output spikes from the neuron.

+

lif, output plot Fig.1 The dynamics of leaky integrate and fire neuron. The grey signal is the input spikes, the yellow signal is the membrane potential and the dark blue is the output spikes from the neuron.

Referennces

  1. Sourikopoulos I, Hedayat S, Loyez C, Danneville F, Hoel V, Mercier E and Cappy A (2017) A 4-fJ/Spike Artificial Neuron in 65 nm CMOS Technology. Front. Neurosci. 11:123. doi: 10.3389/fnins.2017.00123
    2. diff --git a/img/lif_plot.png b/neuron_models/lif/lif_plot.png similarity index 100% rename from img/lif_plot.png rename to neuron_models/lif/lif_plot.png diff --git a/img/exif_plot.png b/neuron_models/snowball/exif_plot.png similarity index 100% rename from img/exif_plot.png rename to neuron_models/snowball/exif_plot.png diff --git a/neuron_models/snowball/index.html b/neuron_models/snowball/index.html index c13e7c9..a03a795 100644 --- a/neuron_models/snowball/index.html +++ b/neuron_models/snowball/index.html @@ -881,7 +881,7 @@

    Input current mirror W/l = 0.2
    All other transistors W/L = 4/3

    Circuit Simulation

    -

    snowball, output plot Fig.1 The dynamics of Exponential integrate and fire neuron. The light blue signal is the input spikes, the yellow signal is the membrane potential and the dark blue is the output spikes from the neuron.

    +

    snowball, output plot Fig.1 The dynamics of Exponential integrate and fire neuron. The light blue signal is the input spikes, the yellow signal is the membrane potential and the dark blue is the output spikes from the neuron.

    References

    1. Rubino, Arianna, Melika Payvand, and Giacomo Indiveri. "Ultra-low power silicon neuron circuit for extreme-edge neuromorphic intelligence." 2019 26th IEEE International Conference on Electronics, Circuits and Systems (ICECS). IEEE, 2019.
      2. diff --git a/print_page/index.html b/print_page/index.html index e567040..8189ac7 100644 --- a/print_page/index.html +++ b/print_page/index.html @@ -3513,7 +3513,7 @@ def plot_vf(ax, neuron_model, u_range, v_range):

      Input current mirror W/l = 0.2
      All other transistors W/L = 4/3

      Circuit Simulation

      -

      snowball, output plot Fig.1 The dynamics of Exponential integrate and fire neuron. The light blue signal is the input spikes, the yellow signal is the membrane potential and the dark blue is the output spikes from the neuron.

      +

      snowball, output plot Fig.1 The dynamics of Exponential integrate and fire neuron. The light blue signal is the input spikes, the yellow signal is the membrane potential and the dark blue is the output spikes from the neuron.

      References

      1. Rubino, Arianna, Melika Payvand, and Giacomo Indiveri. "Ultra-low power silicon neuron circuit for extreme-edge neuromorphic intelligence." 2019 26th IEEE International Conference on Electronics, Circuits and Systems (ICECS). IEEE, 2019.