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Machine learning data set versus time series data set

      Now that you have a better understanding of time series data, it is also important to understand the difference between time series analysis and time series forecasting. These two domains are tightly related, but they serve different purposes: time series analysis is about identifying the intrinsic structure and extrapolating the hidden traits of your time series data in order to get helpful information from it (like trend or seasonal variation—these are all concepts that we will discuss later on in the chapter).

      Data scientists usually leverage time series analysis for the following reasons:

       Acquire clear insights of the underlying structures of historical time series data.

       Increase the quality of the interpretation of time series features to better inform the problem domain.

       Preprocess and perform high-quality feature engineering to get a richer and deeper historical data set.

Illustration of the difference between time series analysis historical input data and time series forecasting output data.

      Different historical and current phenomena may affect the values of your data in a time series, and these events are diagnosed as components of a time series. It is very important to recognize these different influences or components and decompose them in order to separate them from the data levels.

      Let's have a closer look at these four components:

       Long-term movement or trend refers to the overall movement of time series values to increase or decrease during a prolonged time interval. It is common to observe trends changing direction throughout the course of your time series data set: they may increase, decrease, or remain stable at different moments. However, overall you will see one primary trend. Population counts, agricultural production, and items manufactured are just some examples of when trends may come into play.

       There are two different types of short-term movements:Seasonal variations are periodic temporal fluctuations that show the same variation and usually recur over a period of less than a year. Seasonality is always of a fixed and known period. Most of the time, this variation will be present in a time series if the data is recorded hourly, daily, weekly, quarterly, or monthly. Different social conventions (such as holidays and festivities), weather seasons, and climatic conditions play an important role in seasonal variations, like for example the sale of umbrellas and raincoats in the rainy season and the sale of air conditioners in summer seasons.Cyclic variations, on the other side, are recurrent patterns that exist when data exhibits rises and falls that are not of a fixed period. One complete period is a cycle, but a cycle will not have a specific predetermined length of time, even if the duration of these temporal fluctuations is usually longer than a year. A classic example of cyclic variation is a business cycle, which is the downward and upward movement of gross domestic product around its long-term growth trend: it usually can last several years, but the duration of the current business cycle is unknown in advance.As illustrated in Figure 1.5, cyclic variations and seasonal variations are part of the same short-term movements in time series forecasting, but they present differences that data scientists need to identify and leverage in order to build accurate forecasting models:Figure 1.5: Differences between cyclic variations versus seasonal variations

       Random or irregular fluctuations are the last element to cause variations in our time series data. These fluctuations are uncontrollable, unpredictable, and erratic, such as earthquakes, wars, flood, and any other natural disasters.

Graph depicting the actual representation of time series components - seasonal signs, trend sign, random noise, and actual demand line.

      Data scientists need to carefully identify to what extent each component is present in the time series data to be able to build an accurate machine learning forecasting solution. In order to recognize and measure these four components, it is recommended to first perform a decomposition process to remove the component effects from the data. After these components are identified and measured, and eventually utilized to build additional features to improve the forecast accuracy, data scientists can leverage different methods to recompose and add back the components on forecasted results.

      There are two important forms of stationarity: strong stationarity and weak stationarity. A time series is defined as having a strong stationarity when all its statistical

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