鑽石舞台

Warmup

Linear scaling learning rate

Label-smoothing

Random image cropping and patching

Knowledge Distillation

Cutout

Random erasing

Cosine learning rate decay

Mixup training

AdaBoud

AutoAugment

其他經典的tricks

from torch.optim.lr_scheduler import_LRScheduler

classGradualWarmupScheduler(_LRScheduler):

"""

Args:

optimizer (Optimizer): Wrapped optimizer.

multiplier: target learning rate = base lr * multiplier

total_epoch: target learning rate is reached at total_epoch, gradually

after_scheduler: after target_epoch, use this scheduler(eg. ReduceLROnPlateau)

"""

def __init__(self, optimizer, multiplier, total_epoch, after_scheduler=None):

self.multiplier = multiplier

if self.multiplier <= 1.:

raiseValueError('multiplier should be greater than 1.')

self.total_epoch = total_epoch

self.after_scheduler = after_scheduler

self.finished = False

super().__init__(optimizer)

def get_lr(self):

if self.last_epoch > self.total_epoch:

if self.after_scheduler:

ifnot self.finished:

self.after_scheduler.base_lrs = [base_lr * self.multiplier for base_lr in self.base_lrs]

self.finished = True

return self.after_scheduler.get_lr()

return[base_lr * self.multiplier for base_lr in self.base_lrs]

return[base_lr * ((self.multiplier - 1.) * self.last_epoch / self.total_epoch + 1.) for base_lr in self.base_lrs]

def step(self, epoch=None):

if self.finished and self.after_scheduler:

return self.after_scheduler.step(epoch)

else:

return super(GradualWarmupScheduler, self).step(epoch)

import torch

import torch.nn as nn

class LSR(nn.Module):

def __init__(self, e=0.1, reduction='mean'):

super().__init__()

self.log_softmax = nn.LogSoftmax(dim=1)

self.e = e

self.reduction = reduction

def _one_hot(self, labels, classes, value=1):

"""

Convert labels to one hot vectors

Args:

labels: torch tensor in format [label1, label2, label3, ...]

classes: int, number of classes

value: label value in one hot vector, default to 1

Returns:

return one hot format labels in shape [batchsize, classes]

"""

one_hot = torch.zeros(labels.size(0), classes)

#labels and value_added size must match

labels = labels.view(labels.size(0), -1)

value_added = torch.Tensor(labels.size(0), 1).fill_(value)

value_added = value_added.to(labels.device)

one_hot = one_hot.to(labels.device)

one_hot.scatter_add_(1, labels, value_added)

return one_hot

def _smooth_label(self, target, length, smooth_factor):

"""convert targets to one-hot format, and smooth

them.

Args:

target: target in form with [label1, label2, label_batchsize]

length: length of one-hot format(number of classes)

smooth_factor: smooth factor for label smooth

Returns:

smoothed labels in one hot format

"""

one_hot = self._one_hot(target, length, value=1- smooth_factor)

one_hot += smooth_factor / length

return one_hot.to(target.device)

beta = 0.3# hyperparameter

for(images, targets) in train_loader:

# get the image size

I_x, I_y = images.size()[2:]

# draw a boundry position (w, h)

w = int(np.round(I_x * np.random.beta(beta, beta)))

h = int(np.round(I_y * np.random.beta(beta, beta)))

w_ = [w, I_x - w, w, I_x - w]

h_ = [h, h, I_y - h, I_y - h]

# select and crop four images

cropped_images = {}

c_ = {}

W_ = {}

for k in range(4):

index = torch.randperm(images.size(0))

x_k = np.random.randint(0, I_x - w_[k] + 1)

y_k = np.random.randint(0, I_y - h_[k] + 1)

cropped_images[k] = images[index][:, :, x_k:x_k + w_[k], y_k:y_k + h_[k]]

c_[k] = target[index].cuda()

W_[k] = w_[k] * h_[k] / (I_x * I_y)

# patch cropped images

patched_images = torch.cat(

(torch.cat((cropped_images[0], cropped_images[1]), 2),

torch.cat((cropped_images[2], cropped_images[3]), 2)),

3)

#patched_images = patched_images.cuda()

# get output

output = model(patched_images)

# calculate loss and accuracy

loss = sum([W_[k] * criterion(output, c_[k]) for k in range(4)])

acc = sum([W_[k] * accuracy(output, c_[k])[0] for k in range(4)])

import torch

import numpy as np

classCutout(object):

"""Randomly mask out one or more patches from an image.

Args:

n_holes (int): Number of patches to cut out of each image.

length (int): The length (in pixels) of each square patch.

"""

def __init__(self, n_holes, length):

self.n_holes = n_holes

self.length = length

def __call__(self, img):

"""

Args:

img (Tensor): Tensor image of size (C, H, W).

Returns:

Tensor: Image with n_holes of dimension length x length cut out of it.

"""

h = img.size(1)

w = img.size(2)

mask = np.ones((h, w), np.float32)

for n in range(self.n_holes):

y = np.random.randint(h)

x = np.random.randint(w)

y1 = np.clip(y - self.length // 2, 0, h)

y2 = np.clip(y + self.length // 2, 0, h)

x1 = np.clip(x - self.length // 2, 0, w)

x2 = np.clip(x + self.length // 2, 0, w)

mask[y1: y2, x1: x2] = 0.

mask = torch.from_numpy(mask)

mask = mask.expand_as(img)

img = img * mask

return img

from __future__ import absolute_import

from torchvision.transforms import*

from PIL importImage

import random

import math

import numpy as np

import torch

classRandomErasing(object):

'''

probability: The probability that the operation will be performed.

sl: min erasing area

sh: max erasing area

r1: min aspect ratio

mean: erasing value

'''

def __init__(self, probability = 0.5, sl = 0.02, sh = 0.4, r1 = 0.3, mean=[0.4914, 0.4822, 0.4465]):

self.probability = probability

self.mean = mean

self.sl = sl

self.sh = sh

self.r1 = r1

def __call__(self, img):

if random.uniform(0, 1) > self.probability:

return img

for attempt in range(100):

area = img.size()[1] * img.size()[2]

target_area = random.uniform(self.sl, self.sh) * area

aspect_ratio = random.uniform(self.r1, 1/self.r1)

h = int(round(math.sqrt(target_area * aspect_ratio)))

w = int(round(math.sqrt(target_area / aspect_ratio)))

if w < img.size()[2] and h < img.size()[1]:

x1 = random.randint(0, img.size()[1] - h)

y1 = random.randint(0, img.size()[2] - w)

if img.size()[0] == 3:

img[0, x1:x1+h, y1:y1+w] = self.mean[0]

img[1, x1:x1+h, y1:y1+w] = self.mean[1]

img[2, x1:x1+h, y1:y1+w] = self.mean[2]

else:

img[0, x1:x1+h, y1:y1+w] = self.mean[0]

return img

return img

# Assuming optimizer uses lr = 0.05 for all groups

# lr = 0.05 if epoch < 30

# lr = 0.005 if 30 <= epoch < 60

# lr = 0.0005 if 60 <= epoch < 90

from torch.optim.lr_scheduler importStepLR

scheduler = StepLR(optimizer, step_size=30, gamma=0.1)

for epoch in range(100):

scheduler.step()

train(...)

validate(...)

for(images, labels) in train_loader:

l = np.random.beta(mixup_alpha, mixup_alpha)

index = torch.randperm(images.size(0))

images_a, images_b = images, images[index]

labels_a, labels_b = labels, labels[index]

mixed_images = l * images_a + (1- l) * images_b

outputs = model(mixed_images)

loss = l * criterion(outputs, labels_a) + (1- l) * criterion(outputs, labels_b)

acc = l * accuracy(outputs, labels_a)[0] + (1- l) * accuracy(outputs, labels_b)[0]

pip install adabound

optimizer = adabound.AdaBound(model.parameters(), lr=1e-3, final_lr=0.1)

Dropout

L1/L2正則

Batch Normalization

Early stopping

Random cropping

Mirroring

Rotation

Color shifting

PCA color augmentation

...

Xavier init[12]

...