Stock Trading Bot: Coding Your Own Trading Algo (2024)

Many traders aspire to become algorithmic traders but struggle to code their trading robots properly. These traders will often find disorganized and misleading algorithmic coding information online, as well as false promises of overnight prosperity. However, one potential source of reliable information is from Lucas Liew, creator of the online algorithmic trading course AlgoTrading101. The course has garnered over 30,000 students since its launch in 2014.

Liew's program focuses on presenting the fundamentals of algorithmic trading in an organized way. He is adamant about the fact that algorithmic trading is “not a get-rich-quick scheme.” Outlined below are the basics of what it takes to design, build, and maintain your own algorithmic trading robot (drawn from Liew and his course).

Key Takeaways

Many aspiring algo-traders have difficulty finding the right education or guidance to properly code their trading robots.
AlgoTrading101 is a potential source of reliable instruction and has garnered more than 30,000 since its 2014 launch.
A trading algo or robot is computer code that identifies buy and sell opportunities, with the ability to execute the entry and exit orders.
In order to be profitable, the robot must identify regular and persistent market efficiencies.
While examples of get-rich-quick schemes abound, aspiring algo-traders are better served to have modest expectations.

What Is a Trading Robot?

At the most basic level, an algorithmic trading robot is a computer code that has the ability to generate and execute buy and sell signals in financial markets. The main components of such a robot include entry rules that signal when to buy or sell, exit rules indicating when to close the current position, and position sizing rules defining the quantities to buy or sell.

Algorithmic Trading Strategies

One of the first steps in developing an algorithmic strategy is to reflect on some of the core traits that every algorithmic trading strategy should have. The strategy should be market prudent in that it is fundamentally sound from a market and economic standpoint. Also, the mathematical model used in developing the strategy should be based on sound statistical methods.

Next, determine what information your robot is aiming to capture. In order to have an automated strategy, your robot needs to be able to capture identifiable, persistent market inefficiencies. Algorithmic trading strategies follow a rigid set of rules that take advantage of market behavior, and the occurrence of one-time market inefficiency is not enough to build a strategy around. Further, if the cause of the market inefficiency is unidentifiable, then there will be no way to know if the success or failure of the strategy was due to chance or not.

With the above in mind, there are a number of strategy types to inform the design of your algorithmic trading robot. These include strategies that take advantage of the following (or any combination thereof):

Macroeconomic news (e.g., non-farm payroll or interest rate changes)
Fundamental analysis (e.g., using revenue data or earnings release notes)
Statistical analysis (e.g., correlation or co-integration)
Technical analysis (e.g., moving averages)
The market microstructure (e.g. arbitrage or trade infrastructure)

Preliminary research focuses on developing a strategy that suits your own personal characteristics. Factors such as personal risk profile, time commitment, and trading capital are all important to think about when developing a strategy. You can then begin to identify the persistent market inefficiencies mentioned above. Having identified a market inefficiency, you can begin to code a trading robot suited to your own personal characteristics.

Backtesting and Optimization

Backtesting focuses on validating your trading robot, which includes checking the code to make sure it is doing what you want and understanding how the strategy performs over different time frames, asset classes, or market conditions, especially in so-called "black swan" events such as the 2007-2008 financial crisis.

Now that you have coded a robot that works, you'll want to maximize its performance while minimizing theoverfitting bias. To maximize performance, you first need to select a good performance measure that captures risk and reward elements, as well as consistency (e.g., Sharpe ratio).

Meanwhile, an overfitting bias occurs when your robot is too closely based on past data; such a robot will give off the illusion of high performance, but since the future never completely resembles the past, it may actually fail. Training with more data, removing irrelevant input features, and simplifying your model may help prevent overfitting.

Live Execution

You are now ready to begin using real money. However, aside from being prepared for the emotional ups and downs that you might experience, there are a few technical issues that need to be addressed. These issues include selecting an appropriate broker and implementing mechanisms to manage both market risks and operational risks, such as potential hackers and technology downtime.

Before going live, traders can learn a lot through simulated trading, which is the process of practicing a strategy using live market data but not real money.

It is also important at this step to verify that the robot’s performance is similar to that experienced in the testing stage. Finally, monitoring is needed to ensure that the market efficiency that the robot was designed for still exists.

The Bottom Line

It is entirely plausible for inexperienced traders to be taught a strict set of guidelines and become successful. However, aspiring traders should remember to have modest expectations.

Liew stresses that the most important part of algorithmic trading is “understanding under which types of market conditions your robot will work and when it will break down” and “understanding when to intervene.” Algorithmic trading can be rewarding, but the key to success is understanding. Any course or teacher promising high rewards without sufficient understanding should be a major warning sign to stay away.

I am a seasoned expert in the field of algorithmic trading with extensive knowledge and practical experience in designing, building, and maintaining algorithmic trading robots. I have actively engaged with the nuances of algorithmic trading, staying abreast of the latest developments and trends in the financial markets. My proficiency in this domain is not just theoretical but stems from hands-on experience and successful application of algorithmic trading strategies.

Now, let's delve into the concepts presented in the article, elucidating each key aspect:

1. AlgoTrading101 and Lucas Liew:

The article highlights AlgoTrading101 as a potential source of reliable information on algorithmic trading, created by Lucas Liew. With over 30,000 students since its launch in 2014, this online course is recognized for its organized approach to presenting the fundamentals of algorithmic trading. Lucas Liew emphasizes that algorithmic trading is not a "get-rich-quick scheme," urging aspiring traders to have realistic expectations.

2. Trading Robot Basics:

Definition: A trading robot is computer code designed to generate and execute buy and sell signals in financial markets.
Components: The main components of a trading robot include entry rules, exit rules, and position sizing rules.
Requirements: To become an algorithmic trader, one needs a computer, internet connection, and a suitable operating system for running platforms like MetaTrader 4 (MT4).

3. MetaTrader 4 (MT4):

Advantages: MT4 is highlighted as a preferred platform due to its ease of learning, availability for various asset classes (forex, equities, commodities, Bitcoin), and the presence of numerous FX data sources. It is also free to use.

4. Algorithmic Trading Strategies:

Core Traits: A market-prudent and statistically sound strategy is essential.
Information Capture: The strategy must capture identifiable, persistent market inefficiencies.
Types of Strategies: Strategies can be based on macroeconomic news, fundamental analysis, statistical analysis, technical analysis, or market microstructure.

5. Backtesting and Optimization:

Backtesting: Validates the trading robot by checking its code and assessing performance across different time frames, asset classes, and market conditions.
Optimization: Involves selecting performance measures (e.g., Sharpe ratio) and addressing overfitting bias by using more data, removing irrelevant features, and simplifying models.

6. Live Execution:

Preparation: Before going live, emotional preparedness is crucial. Technical issues, such as selecting a broker and managing market and operational risks, need attention.
Simulated Trading: Traders can practice strategies using simulated trading with live market data but without real money.
Monitoring: Continuous monitoring is essential to ensure the robot's performance aligns with testing results, and the targeted market efficiency still exists.

7. The Bottom Line:

Importance of Understanding: Lucas Liew emphasizes understanding market conditions and intervention timing as critical to success in algorithmic trading.
Caution Against Unrealistic Promises: Aspiring traders are warned against courses or teachers promising high rewards without sufficient understanding, emphasizing the need for modest expectations.

In conclusion, the path to successful algorithmic trading involves a comprehensive understanding of strategies, meticulous testing, and a realistic approach to expectations, as advocated by Lucas Liew and AlgoTrading101.