Motivated by "A Deep Reinforcement Learning Framework for the Financial Portfolio Management Problem" by Jiang et. al. 2017 [1]. In this project:
- Implement two state-of-art continous deep reinforcement learning algorithms, Deep Deterministic Policy Gradient (DDPG) and Proximal Policy Optimization(PPO) in portfolio management.
- Experiments on different settings, such as changing learning rates, optimizers, neutral network structures, China/America Stock data, initializers, noise, features to figure out their influence on the RL agents' performance(cumulative return).
The environment provides supports for easily testing different reinforcement learning in portfolio management.
- main.py - the entrance to run our training and testing framework
- ./saved_network- contains different saved models after training, with DDPG and PPO sub folders
- ./summary- contains summaries, also with DDPG and PPO sub folder
- ./agent- contains ddpg.py, ppo.py and ornstein_uhlenbeck.py(the noise we add to agent's actions during training)
- ./data- contains America.csv for USA stock data, China.csv for China stock data. download_data.py can download China stock data by Tushare. environment.py generates states data for trading agents.
- config.json- the configuration file for training or testing settings:
{
"data":{
"start_date":"2015-01-01",
"end_date":"2018-01-01",
"market_types":["stock"],
"ktype":"D"
},
"session":{
"start_date":"2015-01-05",
"end_date":"2017-01-01",
"market_types":"America",
"codes":["AAPL","ADBE","BABA","SNE","V"],
"features":["close"],
"agents":["CNN","DDPG","3"],
"epochs":"10000",
"noise_flag":"False",
"record_flag":"False",
"plot_flag":"False",
"reload_flag":"False",
"trainable":"True",
"method":"model_free"
}
}
Download stock data in shenzhen and shanghai stock market in the given period in Day(D) frequency. Options: hours, minutes
python main.py --mode=download_data
Training/Testing
python main.py --mode=train
python main.py --mode=test
- noise_flag=True: actions produced by RL agents are distorted by adding UO noise.
- record_flag=True: trading details would be stored as a csv file named by the epoch and cumulative return each epoch.
- plot_flag=True: the trend of wealth would be plot each epoch.
- reload_flag=True: tensorflow would search latest saved model in ./saved_network and reload.
- trainable=True: parameters would be updated during each epoch.
- method=model_based: the first epochs our agents would try to imitate a greedy strategy to quickly improve its performance. Then it would leave it and continue to self-improve by model-free reinforcement learning.
-
Training data (USA)
-
Training data (China)
-
Backtest (USA)
-
APV under different feature combinations
The other results can be found in our report.(https://arxiv.org/abs/1808.09940).
- Zhipeng Liang
- Kangkang Jiang
- Hao Chen
- Junhao Zhu
- Yanran Li
- AI&FintechLab of Likelihood Technology
- Sun Yat-sen University
We would like to say thanks to Mingwen Liu from ShingingMidas Private Fund, Zheng Xie and Xingyu Fu from Sun Yat-sen University for their generous guidance throughout the project.
Python Version
- 3.6
Modules needed
- tensorflow(tensorflow-gpu)
- numpy
- pandas
- matplotlib