def __init__(self, T: int, channels: int, use_cupy=False):
super().__init__()
self.T = T
self.conv_fc = nn.Sequential(
layer.Conv2d(1, channels, kernel_size=3, padding=1, bias=False),
layer.BatchNorm2d(channels),
neuron.IFNode(surrogate_function=surrogate.ATan()),
layer.MaxPool2d(2, 2), # 14 * 14
layer.Conv2d(channels,
channels,
kernel_size=3,
padding=1,
bias=False),
layer.BatchNorm2d(channels),
neuron.IFNode(surrogate_function=surrogate.ATan()),
layer.MaxPool2d(2, 2), # 7 * 7
layer.Flatten(),
layer.Linear(channels * 7 * 7, channels * 4 * 4, bias=False),
neuron.IFNode(surrogate_function=surrogate.ATan()),
layer.Linear(channels * 4 * 4, 10, bias=False),
neuron.IFNode(surrogate_function=surrogate.ATan()),
)
functional.set_step_mode(self, step_mode='m')
if use_cupy:
functional.set_backend(self, backend='cupy')
def __init__(self):
super().__init__()
self.fc = nn.Sequential(
layer.Linear(28, 32),
neuron.IFNode(surrogate_function=surrogate.ATan()),
layer.Linear(32, 10),
neuron.IFNode(surrogate_function=surrogate.ATan())
)
def __init__(self):
super().__init__()
self.fc = nn.Sequential(
layer.Linear(28, 32),
neuron.IFNode(surrogate_function=surrogate.ATan()),
layer.SynapseFilter(tau=2., learnable=True),
layer.Linear(32, 10),
neuron.IFNode(surrogate_function=surrogate.ATan())
)
def __init__(self):
super().__init__()
self.fc = nn.Sequential(
layer.Linear(28, 32),
layer.LinearRecurrentContainer(
neuron.IFNode(surrogate_function=surrogate.ATan(), detach_reset=True),
in_features=32, out_features=32, bias=True
),
layer.Linear(32, 10),
neuron.IFNode(surrogate_function=surrogate.ATan())
)
def __init__(self, num_inputs, num_outputs, hidden_size, T=16):
super(ActorCritic, self).__init__()
self.critic = nn.Sequential(nn.Linear(num_inputs, hidden_size),
neuron.IFNode(), nn.Linear(hidden_size, 1),
NonSpikingLIFNode(tau=2.0))
self.actor = nn.Sequential(nn.Linear(num_inputs, hidden_size),
neuron.IFNode(),
nn.Linear(hidden_size, num_outputs),
NonSpikingLIFNode(tau=2.0))
self.T = T
def __init__(self, hidden_num):
super().__init__()
self.fc = nn.Sequential(
nn.Linear(4, hidden_num),
neuron.IFNode(),
nn.Linear(hidden_num, 2),
NonSpikingLIFNode(tau=2.0)
)
self.T = 16
def __init__(self,
num_inputs,
num_outputs,
hidden_size,
T=16,
std=0.0):
super(ActorCritic, self).__init__()
self.critic = nn.Sequential(nn.Linear(num_inputs, hidden_size),
neuron.IFNode(),
nn.Linear(hidden_size, 1),
NonSpikingLIFNode(tau=2.0))
self.actor = nn.Sequential(nn.Linear(num_inputs, hidden_size),
neuron.IFNode(),
nn.Linear(hidden_size, num_outputs),
NonSpikingLIFNode(tau=2.0))
self.log_std = nn.Parameter(torch.ones(1, num_outputs) * std)
self.T = T
def replace_by_ifnode(model):
for name, module in model._modules.items():
if hasattr(module, "_modules"):
model._modules[name] = Converter.replace_by_ifnode(module)
if module.__class__.__name__ == 'Sequential' and len(module) == 2 and \
module[0].__class__.__name__ == 'ReLU' and \
module[1].__class__.__name__ == 'VoltageHook':
s = module[1].scale.item()
model._modules[name] = nn.Sequential(
VoltageScaler(1.0 / s),
neuron.IFNode(v_threshold=1., v_reset=None),
VoltageScaler(s))
return model
from matplotlib import pyplot as plt
import torch
from spikingjelly.activation_based import neuron
from spikingjelly import visualizing
import numpy as np
import matplotlib
with torch.no_grad():
# Requires SciencePlots package: https://github.com/garrettj403/SciencePlots
plt.style.use(['science'])
if_node = neuron.IFNode(v_reset=None, monitor_state=True)
T = 25
x = torch.arange(0, 1.04, 0.04)
for t in range(T):
if_node(x)
s_t_array = np.asarray(
if_node.monitor['s']).T # s_t_array[i][j]表示神经元i在j时刻释放的脉冲,为0或1
v_t_array = np.asarray(
if_node.monitor['v']).T # v_t_array[i][j]表示神经元i在j时刻的电压值
fig = plt.figure(dpi=125, tight_layout=True)
gs = matplotlib.gridspec.GridSpec(2, 5)
# plot_1d_spikes
spikes_map = fig.add_subplot(gs[0, :4])
firing_rate_map = fig.add_subplot(gs[0, 4])
spikes_map.set_title('Spike Events')
spikes_map.set_xlabel('t')