pytrendseries is a Python library for detection of trends in time series like: stock prices, monthly sales, daily temperature of a city and so on.
The input data must be a pandas.DataFrame format containing one column as observed data (in float or int format). Follow example below:
import pandas as pd
data = pd.read_csv("tests/resource/stock_prices.csv")
filtered_data = data[['period','close']].set_index("period")
filtered_data.columns = ['close_price']
filtered_data.index = pd.to_datetime(filtered_data.index)
filtered_data = filtered_data.sort_index()Once some trend is identified, pytrendseries provides period on trend, drawdown, maximum drawdown (or drawup in case of uptrend) and a plot with all trends found.
You can install using the pip package manager by running:
pip install pytrendseriesAlternatively, you could install the latest version directly from Github:
python -m pip install git+https://github.com/rafa-rod/pytrendseries.gitDetection of trends could be used in machine learning algorithms such as classification problems like binary (1 = uptrend, 0 = otherwise) or non-binary classifications (1 = uptrend, -1 = downtrend, 0 = otherwise). Besides that, could be used in prediction problems.
Inform:
- type of trend you desire to investigate => downtrend or uptrend;
- window or maximum period of a trend (example: 60 days considering 1 day as 1 period);
- the minimum value that represents the number of consecutive days (or another period of time) to be considered a trend (default 5 periods).
import pytrendseries
trend = "downtrend"
window = 126 #6 months
trends_detected = pytrendseries.detecttrend(filtered_data, trend=trend, window=window)The variable trends_detected is a dataframe that contains the initial and end date of each trend, the prices of each date, time span of each trend and the drawdown of each trend. Let's see the first five rows of this dataframe:
| Peak Date | Valley Date | Peak | Valley | index_peak |index_valley | time_span | drawdown |
|:--------------------|:--------------------|---------:|---------:|--------------:|------------:|------------:|-----------:|
| 2000-01-03 00:00:00 | 2000-01-31 00:00:00 | 5.90057 | 5.12252 | 0 | 19 | 19 | 0.131859 |
| 2000-03-09 00:00:00 | 2000-04-24 00:00:00 | 6.42701 | 5.02208 | 45 | 76 | 31 | 0.218597 |
| 2000-05-02 00:00:00 | 2000-05-11 00:00:00 | 5.53684 | 5.29352 | 81 | 88 | 7 | 0.0439456 |
| 2000-05-16 00:00:00 | 2000-05-24 00:00:00 | 5.59962 | 5.24807 | 91 | 97 | 6 | 0.0627803 |
| 2000-06-08 00:00:00 | 2000-06-15 00:00:00 | 6.30359 | 6.1646 | 108 | 113 | 5 | 0.0220487 |
The easiest way to vizualize the trends detected, just call plot_trend function.
All trends detected, with maximum window informed and the minimum informed by the limit value, will be displayed.
import pytrendseries
trend = "downtrend"
window = 30
year = 2020
trends_detected = pytrendseries.detecttrend(filtered_data, trend=trend, window=window)
pytrendseries.vizplot.plot_trend(filtered_data, trends_detected, trend, year)
To visualize all uptrends found, inform trend='uptrend':
import pytrendseries
window = 30
year = 2020
trends_detected = pytrendseries.detecttrend(filtered_data, trend='uptrend', window=window)
pytrendseries.vizplot.plot_trend(filtered_data, trends_detected, 'uptrend', year)
The maxdrawdown calculates the Maximum Drawdown within non-overlapping time windows, providing detailed information about each significant drawdown event.
The maximum drawdown or maximum drawup can be obtained by sorting the dataframe by column drawdown. To do that, just code:
maxdd_in_window = trends_detected.sort_values("drawdown", ascending=False).iloc[0:1]Another way is to call the function maxdrawdown. Note that this result will be differente once the maximum drawdown of the intire timeseries, unless you pass same window parameter.
maxdd = pytrendseries.maxdrawdown(filtered_data, window=None)Output includes:
- Window Start/End dates;
- Peak and Valley dates with corresponding prices;
- Maximum Drawdown percentage;
- Time Span (number of periods from peak to valley).
You can code to vizualize as follows:
import matplotlib.pyplot as plt
plt.figure(figsize=(14,5))
plt.plot(filtered_data, alpha=0.6)
location_x = maxdd.values[:,0]
location_y = maxdd.values[:,1]
for i in range(location_x.shape[0]):
plt.axvspan(location_x[i], location_y[i], alpha=0.3, color="red")
plt.grid(axis='x')
plt.show()
You may pass the parameter window to obtain the same result:
maxdd_in_window = pytrendseries.maxdrawdown(filtered_data, window=252)To vizualize all drawdowns of timeseries, call the following function:
import pytrendseries
pytrendseries.plot_drawdowns(filtered_data, figsize = (10,4), color="gray", alpha=0.6, title="Drawdowns", axis="y")
Another option is:
import pytrendseries
pytrendseries.plot_evolution(filtered_data, figsize = (10,4), colors=["gray", "red"], alphas=[1,0.6])
The calculate_current_drawdown function returns key metrics including the current price, last peak value and date, current drawdown percentage, and the duration (in number of records) since the last peak.
import pytrendseries
pytrendseries.calculate_current_drawdown(filtered_data)Output example:
| current_price | last_peak | current_drawdown | last_peak_date | time_in_drawdown |
|---|---|---|---|---|
| 98.50 | 105.30 | -6.46% | 2024-01-15 | 12 |
To get time underwater (tuw), just type:
import pytrendseries
pytrendseries.calculate_time_under_water(filtered_data)The output would be (showing the tail of the dataframe):
| Peak Date | Recovery Date | Peak | Valley | MaxDD | Time Underwater | Status |
|:----------|:--------------|---------:|----------:|----------:|----------------:|-----------:|
| 2007-12-28| 2008-05-06 | 44.66140 | 33.58194 | 0.24808 | 85 | Recovered |
| 2008-05-06| 2008-05-09 | 45.00000 | 44.85000 | 0.00333 | 4 | Recovered |
| 2008-05-13| 2008-05-15 | 46.95000 | 46.30000 | 0.01384 | 3 | Recovered |
| 2008-05-21| NaT | 52.51000 | 4.20000 | 0.92002 | 235 | Ongoing |
The Status column indicates whether the drawdown period has recovered or is still ongoing, while Time Underwater shows the number of periods spent below the previous peak.
Another important usage of pytrendseries is to obtain the series of drawdowns or series of maximum drawdowns in order to calculate the drawdown at risk or maximum drawdown at risk.
import pytrendseries
import matplotlib.pyplot as plt
import seaborn as sns; sns.set_style("white")
trend = "downtrend"
window = 126 #6 months
trends_detected = pytrendseries.detecttrend(filtered_data, trend=trend, window=window)
plt.figure(figsize=(15,5))
sns.histplot(trends_detected["drawdown"]*100, kde=True, bins=30)
plt.ylabel("")
plt.box(False)
plt.annotate('Maximum Drawdown', xy=((trends_detected["drawdown"].max()-0.005)*100, 1),
xycoords='data',
xytext=(-105, 30), textcoords='offset points',color="red",
weight='bold',
arrowprops=dict(arrowstyle="->", color="r",
connectionstyle='arc3,rad=-0.1'))
plt.annotate('Quantile 97,5%', xy=((trends_detected["drawdown"].quantile(0.975)-0.005)*100, 0.2),
xycoords='data',
xytext=(-135, 30), textcoords='offset points',color="red",
weight='bold',
arrowprops=dict(arrowstyle="->", color="r",
connectionstyle='arc3,rad=-0.1'))
plt.xlabel("Drawdown (%)")
plt.ylabel("Density", rotation=0, labelpad=-30, loc="top")
plt.show()
import pytrendseries
import matplotlib.pyplot as plt
import seaborn as sns; sns.set_style("white")
maxdd_in_window = pytrendseries.maxdrawdown(filtered_data, window=126)
plt.figure(figsize=(15,5))
sns.histplot(maxdd_in_window["MaxDD"]*100, kde=True, bins=30)
plt.ylabel("")
plt.box(False)
plt.annotate('Maximum Drawdown', xy=((maxdd_in_window["MaxDD"].max()-0.005)*100, 1),
xycoords='data',
xytext=(-105, 30), textcoords='offset points',color="red",
weight='bold',
arrowprops=dict(arrowstyle="->", color="r",
connectionstyle='arc3,rad=-0.1'))
plt.annotate('Quantile 95%', xy=((maxdd_in_window["MaxDD"].quantile(0.95)-0.005)*100, 0.2),
xycoords='data',
xytext=(-135, 50), textcoords='offset points',color="red",
weight='bold',
arrowprops=dict(arrowstyle="->", color="r",
connectionstyle='arc3,rad=-0.1'))
plt.xlabel("Maximum Drawdowns (%)")
plt.ylabel("Density", rotation=0, labelpad=-30, loc="top")
plt.show()
The get_trends_labels function automates the process of labeling financial time series data based on detected market structures. By identifying peaks and valleys within a specified window, it segments the data into Uptrends, Downtrends, and No Trend periods.
This function is particularly useful for supervised learning classification problems. Instead of trying to predict the exact future price (a regression problem), you can train models to predict the market state or direction.
- Target Variable Engineering: Converts raw price data into discrete classes (e.g.,
1,-1,0). - Noise Reduction: Ignores minor fluctuations by focusing on significant trends defined by the
windowandlimitparameters. - Flexibility: Allows custom labeling schemes (e.g., numeric for models, strings for interpretability).
After running the function, your dataframe will include a new label column indicating the market regime for each date.
| Date | Close | Label | Market State |
|---|---|---|---|
| 2023-01-03 | 100.5 | 0 | No Trend |
| 2023-01-04 | 101.2 | 0 | No Trend |
| 2023-01-05 | 103.5 | 1 | Uptrend |
| 2023-01-06 | 105.0 | 1 | Uptrend |
| 2023-01-09 | 104.8 | 1 | Uptrend |
| 2023-01-10 | 102.0 | 0 | No Trend |
| 2023-01-11 | 99.5 | -1 | Downtrend |
| 2023-01-12 | 98.0 | -1 | Downtrend |
Uses standard numeric labels (1 for uptrend, -1 for downtrend, 0 for no trend).
import pytrendseries
df_labeled = pytrendseries.get_trends_labels(df, window=252, limit=5)Useful for interpretability or specific model requirements.
custom_labels = {
"uptrend": "BUY",
"downtrend": "SELL",
"notrend": "HOLD"
}
df_labeled = pytrendseries.get_trends_labels(df, labels=custom_labels)Ignore downtrends and treat them as "no trend" for a specific strategy.
binary_labels = {
"uptrend": 1,
"notrend": 0
}
df_labeled = pytrendseries.get_trends_labels(df, labels=binary_labels)