Table of Contents
Fashion-MNIST
is a dataset of Zalando's article images—consisting of a training set of 60,000 examples and a test set of 10,000 examples. Each example is a 28x28 grayscale image, associated with a label from 10 classes. We intend Fashion-MNIST
to serve as a direct drop-in replacement for the original MNIST dataset for benchmarking machine learning algorithms. It shares the same image size and structure of training and testing splits.
Here's an example how the data looks (each class takes three-rows):
The original MNIST dataset contains a lot of handwritten digits. Members of the AI/ML/Data Science community love this dataset and use it as a benchmark to validate their algorithms. In fact, MNIST is often the first dataset researchers try. "If it doesn't work on MNIST, it won't work at all", they said. "Well, if it does work on MNIST, it may still fail on others."
Seriously, we are talking about replacing MNIST. Here are some good reasons:
- MNIST is too easy. Convolutional nets can achieve 99.7% on MNIST. Classic machine learning algorithms can also achieve 97% easily. Check out our side-by-side benchmark for Fashion-MNIST vs. MNIST, and read "Most pairs of MNIST digits can be distinguished pretty well by just one pixel."
- MNIST is overused. In this April 2017 Twitter thread, Google Brain research scientist and deep learning expert Ian Goodfellow calls for people to move away from MNIST.
- MNIST can not represent modern CV tasks, as noted in this April 2017 Twitter thread, deep learning expert/Keras author François Chollet.
Many ML libraries already include Fashion-MNIST data/API, give it a try!
You can use direct links to download the dataset. The data is stored in the same format as the original MNIST data.
Name | Content | Examples | Size | Link | MD5 Checksum |
---|---|---|---|---|---|
train-images-idx3-ubyte.gz |
training set images | 60,000 | 26 MBytes | Download | 8d4fb7e6c68d591d4c3dfef9ec88bf0d |
train-labels-idx1-ubyte.gz |
training set labels | 60,000 | 29 KBytes | Download | 25c81989df183df01b3e8a0aad5dffbe |
t10k-images-idx3-ubyte.gz |
test set images | 10,000 | 4.3 MBytes | Download | bef4ecab320f06d8554ea6380940ec79 |
t10k-labels-idx1-ubyte.gz |
test set labels | 10,000 | 5.1 KBytes | Download | bb300cfdad3c16e7a12a480ee83cd310 |
Alternatively, you can clone this GitHub repository; the dataset appears under data/fashion
. This repo also contains some scripts for benchmark and visualization.
git clone [email protected]:zalandoresearch/fashion-mnist.git
Each training and test example is assigned to one of the following labels:
Label | Description |
---|---|
0 | T-shirt/top |
1 | Trouser |
2 | Pullover |
3 | Dress |
4 | Coat |
5 | Sandal |
6 | Shirt |
7 | Sneaker |
8 | Bag |
9 | Ankle boot |
Loading data with Python (requires NumPy)
Use utils/mnist_reader
in this repo:
import mnist_reader
X_train, y_train = mnist_reader.load_mnist('data/fashion', kind='train')
X_test, y_test = mnist_reader.load_mnist('data/fashion', kind='t10k')
Make sure you have downloaded the data and placed it in data/fashion
. Otherwise, Tensorflow will download and use the original MNIST.
from tensorflow.examples.tutorials.mnist import input_data
data = input_data.read_data_sets('data/fashion')
data.train.next_batch(BATCH_SIZE)
Note, Tensorflow supports passing in a source url to the read_data_sets
. You may use:
data = input_data.read_data_sets('data/fashion', source_url='http://fashion-mnist.s3-website.eu-central-1.amazonaws.com/')
Also, an official Tensorflow tutorial of using tf.keras
, a high-level API to train Fashion-MNIST can be found here.
To date, the following libraries have included Fashion-MNIST
as a built-in dataset. Therefore, you don't need to download Fashion-MNIST
by yourself. Just follow their API and you are ready to go.
You are welcome to make pull requests to other open-source machine learning packages, improving their support to Fashion-MNIST
dataset.
As one of the Machine Learning community's most popular datasets, MNIST has inspired people to implement loaders in many different languages. You can use these loaders with the Fashion-MNIST
dataset as well. (Note: may require decompressing first.) To date, we haven't yet tested all of these loaders with Fashion-MNIST.
We built an automatic benchmarking system based on scikit-learn
that covers 129 classifiers (but no deep learning) with different parameters. Find the results here.
You can reproduce the results by running benchmark/runner.py
. We recommend building and deploying this Dockerfile.
You are welcome to submit your benchmark; simply create a new issue and we'll list your results here. Before doing that, please make sure it does not already appear in this list. Visit our contributor guidelines for additional details.
The table below collects the submitted benchmarks. Note that we haven't yet tested these results. You are welcome to validate the results using the code provided by the submitter. Test accuracy may differ due to the number of epoch, batch size, etc. To correct this table, please create a new issue.
Classifier | Preprocessing | Fashion test accuracy | MNIST test accuracy | Submitter | Code |
---|---|---|---|---|---|
2 Conv+pooling | None | 0.876 | - | Kashif Rasul | 🔗 |
2 Conv+pooling | None | 0.916 | - | Tensorflow's doc | 🔗 |
2 Conv+pooling+ELU activation (PyTorch) | None | 0.903 | - | @AbhirajHinge | 🔗 |
2 Conv | Normalization, random horizontal flip, random vertical flip, random translation, random rotation. | 0.919 | 0.971 | Kyriakos Efthymiadis | 🔗 |
2 Conv <100K parameters | None | 0.925 | 0.992 | @hardmaru | 🔗 |
2 Conv ~113K parameters | Normalization | 0.922 | 0.993 | Abel G. | 🔗 |
2 Conv+3 FC ~1.8M parameters | Normalization | 0.932 | 0.994 | @Xfan1025 | 🔗 |
2 Conv+3 FC ~500K parameters | Augmentation, batch normalization | 0.934 | 0.994 | @cmasch | 🔗 |
2 Conv+pooling+BN | None | 0.934 | - | @khanguyen1207 | 🔗 |
2 Conv+2 FC | Random Horizontal Flips | 0.939 | - | @ashmeet13 | 🔗 |
3 Conv+2 FC | None | 0.907 | - | @Cenk Bircanoğlu | 🔗 |
3 Conv+pooling+BN | None | 0.903 | 0.994 | @meghanabhange | 🔗 |
3 Conv+pooling+2 FC+dropout | None | 0.926 | - | @Umberto Griffo | 🔗 |
3 Conv+BN+pooling | None | 0.921 | 0.992 | @GunjanChhablani | 🔗 |
5 Conv+BN+pooling | None | 0.931 | - | @Noumanmufc1 | 🔗 |
CNN with optional shortcuts, dense-like connectivity | standardization+augmentation+random erasing | 0.947 | - | @kennivich | 🔗 |
GRU+SVM | None | 0.888 | 0.965 | @AFAgarap | 🔗 |
GRU+SVM with dropout | None | 0.897 | 0.988 | @AFAgarap | 🔗 |
WRN40-4 8.9M params | standard preprocessing (mean/std subtraction/division) and augmentation (random crops/horizontal flips) | 0.967 | - | @ajbrock | 🔗 🔗 |
DenseNet-BC 768K params | standard preprocessing (mean/std subtraction/division) and augmentation (random crops/horizontal flips) | 0.954 | - | @ajbrock | 🔗 🔗 |
MobileNet | augmentation (horizontal flips) | 0.950 | - | @苏剑林 | 🔗 |
ResNet18 | Normalization, random horizontal flip, random vertical flip, random translation, random rotation. | 0.949 | 0.979 | Kyriakos Efthymiadis | 🔗 |
GoogleNet with cross-entropy loss | None | 0.937 | - | @Cenk Bircanoğlu | 🔗 |
AlexNet with Triplet loss | None | 0.899 | - | @Cenk Bircanoğlu | 🔗 |
SqueezeNet with cyclical learning rate 200 epochs | None | 0.900 | - | @snakers4 | 🔗 |
Dual path network with wide resnet 28-10 | standard preprocessing (mean/std subtraction/division) and augmentation (random crops/horizontal flips) | 0.957 | - | @Queequeg | 🔗 |
MLP 256-128-100 | None | 0.8833 | - | @heitorrapela | 🔗 |
VGG16 26M parameters | None | 0.935 | - | @QuantumLiu | 🔗 🔗 |
WRN-28-10 | standard preprocessing (mean/std subtraction/division) and augmentation (random crops/horizontal flips) | 0.959 | - | @zhunzhong07 | 🔗 |
WRN-28-10 + Random Erasing | standard preprocessing (mean/std subtraction/division) and augmentation (random crops/horizontal flips) | 0.963 | - | @zhunzhong07 | 🔗 |
Human Performance | Crowd-sourced evaluation of human (with no fashion expertise) performance. 1000 randomly sampled test images, 3 labels per image, majority labelling. | 0.835 | - | Leo | - |
Capsule Network 8M parameters | Normalization and shift at most 2 pixel and horizontal flip | 0.936 | - | @XifengGuo | 🔗 |
HOG+SVM | HOG | 0.926 | - | @subalde | 🔗 |
XgBoost | scaling the pixel values to mean=0.0 and var=1.0 | 0.898 | 0.958 | @anktplwl91 | 🔗 |
DENSER | - | 0.953 | 0.997 | @fillassuncao | 🔗 🔗 |
Dyra-Net | Rescale to unit interval | 0.906 | - | @Dirk Schäfer | 🔗 🔗 |
Google AutoML | 24 compute hours (higher quality) | 0.939 | - | @Sebastian Heinz | 🔗 |
- Tensorflow implementation of various GANs and VAEs. (Recommend to read! Note how various GANs generate different results on Fashion-MNIST, which can not be easily observed on the original MNIST.)
- Make a ghost wardrobe using DCGAN
- fashion-mnist的gan玩具
- CGAN output after 5000 steps
- GAN Playground - Explore Generative Adversarial Nets in your Browser
- Xifeng Guo's implementation of Unsupervised Deep Embedding for Clustering Analysis (DEC)
- Leland McInnes's Uniform Manifold Approximation and Projection (UMAP)
Machine Learning Meets Fashion by Yufeng G @ Google Cloud
Introduction to Kaggle Kernels by Yufeng G @ Google Cloud
动手学深度学习 by Mu Li @ Amazon AI
Apache MXNet으로 배워보는 딥러닝(Deep Learning) - 김무현 (AWS 솔루션즈아키텍트)
UMAP on Fashion-MNIST (left) and original MNIST (right)
Thanks for your interest in contributing! There are many ways to get involved; start with our contributor guidelines and then check these open issues for specific tasks.
To discuss the dataset, please use .
If you use Fashion-MNIST in a scientific publication, we would appreciate references to the following paper:
Fashion-MNIST: a Novel Image Dataset for Benchmarking Machine Learning Algorithms. Han Xiao, Kashif Rasul, Roland Vollgraf. arXiv:1708.07747
Biblatex entry:
@online{xiao2017/online,
author = {Han Xiao and Kashif Rasul and Roland Vollgraf},
title = {Fashion-MNIST: a Novel Image Dataset for Benchmarking Machine Learning Algorithms},
date = {2017-08-28},
year = {2017},
eprintclass = {cs.LG},
eprinttype = {arXiv},
eprint = {cs.LG/1708.07747},
}
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