Search icon CANCEL
Subscription
0
Cart icon
Your Cart (0 item)
Close icon
You have no products in your basket yet
Arrow left icon
Explore Products
Best Sellers
New Releases
Books
Videos
Audiobooks
Learning Hub
Free Learning
Arrow right icon
Modern Time Series Forecasting with Python
Modern Time Series Forecasting with Python

Modern Time Series Forecasting with Python: Explore industry-ready time series forecasting using modern machine learning and deep learning

eBook
€21.99 €31.99
Paperback
€39.99
Subscription
Free Trial
Renews at €18.99p/m

What do you get with Print?

Product feature icon Instant access to your digital eBook copy whilst your Print order is Shipped
Product feature icon Paperback book shipped to your preferred address
Product feature icon Download this book in EPUB and PDF formats
Product feature icon Access this title in our online reader with advanced features
Product feature icon DRM FREE - Read whenever, wherever and however you want
Product feature icon AI Assistant (beta) to help accelerate your learning
OR
Modal Close icon
Payment Processing...
tick Completed

Shipping Address

Billing Address

Shipping Methods
Table of content icon View table of contents Preview book icon Preview Book

Modern Time Series Forecasting with Python

Introducing Time Series

Welcome to Advanced Time Series Analysis Using Python! This book is intended for data scientists or machine learning (ML) engineers who want to level up their time series analysis skills by learning new and advanced techniques from the ML world. Time series analysis is something that is commonly overlooked in regular ML books, courses, and so on. They typically start with classification, touch upon regression, and then move on. But it is also something that is immensely valuable and ubiquitous in business. As long as time is one of the four dimensions in the world we live in, time series data is all-pervasive.

Analyzing time series data unlocks a lot of value for a business. Time series analysis isn't new—it's been around since the 1920s and 1930s. But in the current age of data, the time series that are collected by businesses are growing larger and wider by the minute. Combined with an explosion in the quantum of data collected and the renewed interest in ML, the landscape of time series analysis also changed considerably. This book attempts to take you beyond classical statistical methods such as AutoRegressive Integrated Moving Average (ARIMA) and introduce to you the latest techniques from the ML world in time series analysis.

We are going to start with the basics and quickly scale up to more complex topics. In this chapter, we're going to cover the following main topics:

  • What is a time series?
  • Data-generating process (DGP)
  • What can we forecast?
  • Forecasting terminology and notation

Technical requirements

You will need to set up the Anaconda environment following the instructions in the Preface of the book to get a working environment with all the packages and datasets required for the code in this book.

The associated code for the chapter can be found at https://github.com/PacktPublishing/Modern-Time-Series-Forecasting-with-Python-/tree/main/notebooks/Chapter01.

What is a time series?

To keep it simple, a time series is a set of observations taken sequentially in time. The focus is on the word time. If we keep taking the same observation at different points in time, we will get a time series. For example, if you keep recording the number of bars of chocolate you have in a month, you'll end up with a time series of your chocolate consumption. Suppose you are recording your weight at the beginning of every month. You get another time series of your weight. Is there any relation between the two time series? Most likely, yeah. But we can analyze that scientifically by the end of this book.

A few other examples of time series are the weekly closing price of a stock that you follow, daily rainfall or snow in your city, or hourly readings of your heartbeat from your smartwatch.

Types of time series

There are two types of time series data, as outlined here:

  • Regular time series: This is the most common type of time series where we have observations coming in at regular intervals of time, such as every hour or every month.
  • Irregular time series: There are a few time series where we do not have observations at a regular interval of time. For example, consider we have a sequence of readings from lab tests of a patient. We see an observation in the time series only when the patient heads to the clinic and carries out the lab test, and this may not happen in regular intervals of time.

Important note

This book only focuses on regular time series, which are evenly spaced in time. Irregular time series are slightly more advanced and require specialized techniques to handle them. A couple of survey papers on the topic is a good way to get started on irregular time series and you can find them in the Further reading section of this chapter.

Main areas of application for time series analysis

There are broadly three important areas of application for time series analysis, outlined as follows:

  • Time series forecasting: Predicting the future values of a time series, given the past values—for example, predict the next day's temperature using the last 5 years of temperature data.
  • Time series classification: Sometimes, instead of predicting the future value of the time series, we may also want to predict an action based on past values. For example, given a history of an electroencephalogram (EEG; tracking electrical activity in the brain) or an electrocardiogram (EKG; tracking electrical activity in the heart), we need to predict whether the result of an EEG or an EKG is normal or abnormal.
  • Interpretation and causality: Understand the whats and whys of the time series based on the past values, understand the interrelationships among several related time series, or derive causal inference based on time series data.

Important note

The focus of this book is predominantly on time series forecasting, but the techniques that you learn will help you approach time series classification problems also, with minimal change in the approach. Interpretation is also addressed, although only briefly, but causality is an area that this book does not address because it warrants a whole different approach.

Now that we have an overview of the time series landscape, let's build a mental model on how time series data is generated.

Data-generating process (DGP)

We saw that time series data is a collection of observations made sequentially along the time dimension. Any time series is, in turn, generated by some kind of mechanism. For example, time series data of daily shipments of your favorite chocolate from the manufacturing plant is affected by a lot of factors such as the time of the year, the holiday season, the availability of cocoa, the uptime of the machines working on the plant, and so on. In statistics, this underlying process that generated the time series is referred to as the DGP. Often, time series data is generated by a stochastic process.

If we had complete and perfect knowledge of reality, all we must do is put this DGP together in a mathematical form and you will get the most accurate forecast possible. But sadly, nobody has complete and perfect knowledge of reality. So, what we try to do is approximate the DGP, mathematically, as much as possible so that our imitation of the DGP gives us the best possible forecast (or any other output we want from the analysis). This imitation is called a model that provides a useful approximation to the DGP.

But we must remember that the model is not the DGP, but a representation of some essential aspects of reality. For example, let's consider an aerial view of Bengaluru and a map of Bengaluru, as represented here:

Figure 1.1 – An aerial view of Bengaluru (left) and a map of Bengaluru (right)

Figure 1.1 – An aerial view of Bengaluru (left) and a map of Bengaluru (right)

The map of Bengaluru is certainly useful—we can use it to go from point A to point B. But a map of Bengaluru is not the same as a photo of Bengaluru. It doesn't showcase the bustling nightlife or the insufferable traffic. A map is just a model that represents some useful features of a location, such as roads and places. The following diagram might help us internalize the concept and remember it:

Figure 1.2 – DGP, model, and time series

Figure 1.2 – DGP, model, and time series

Naturally, the next question would be this: Do we have a useful model? Every model is unrealistic. As we saw already, a map of Bengaluru does not perfectly represent Bengaluru. But if our purpose is to navigate Bengaluru, then a map is a very useful model. What if we want to understand the culture? A map doesn't give you a flavor of that. So, now, the same model that was useful is utterly useless in the new context.

Different kinds of models are required in different situations and for different objectives. For example, the best model for forecasting may not be the same as the best model to make a causal inference.

We can use the concept of DGPs to generate multiple synthetic time series, of varying degrees of complexity.

Generating synthetic time series

Let's take a look at a few practical examples where we can generate a few time series using a set of fundamental building blocks. You can get creative and mix and match any of these components, or even add them together to generate a time series of arbitrary complexity.

White and red noise

An extreme case of a stochastic process that generates a time series is a white noise process. It has a sequence of random numbers with zero mean and constant standard deviation. This is also one of the most popular assumptions of noise in a time series.

Let's see how we can generate such a time series and plot it, as follows:

# Generate the time axis with sequential numbers upto 200
time = np.arange(200)
# Sample 200 hundred random values
values = np.random.randn(200)*100
plot_time_series(time, values, "White Noise")

Here is the output:

Figure 1.3 – White noise process

Figure 1.3 – White noise process

Red noise, on the other hand, has zero mean and constant variance but is serially correlated in time. This serial correlation or redness is parameterized by a correlation coefficient r, such that:

where w is a random sample from a white noise distribution.

Let's see how we can generate that, as follows:

# Setting the correlation coefficient
r = 0.4
# Generate the time axis
time = np.arange(200)
# Generate white noise
white_noise = np.random.randn(200)*100
# Create Red Noise by introducing correlation between subsequent values in the white noise
values = np.zeros(200)
for i, v in enumerate(white_noise):
    if i==0:
        values[i] = v
    else:
        values[i] = r*values[i-1]+ np.sqrt((1-np.power(r,2))) *v
plot_time_series(time, values, "Red Noise Process")

Here is the output:

Figure 1.4 – Red noise process

Figure 1.4 – Red noise process

Cyclical or seasonal signals

Among the most common signals you see in time series are seasonal or cyclical signals. Therefore, you can introduce seasonality into your generated series in a few ways.

Let's take the help of a very useful library to generate the rest of the time series—TimeSynth. For more information, refer to https://github.com/TimeSynth/TimeSynth.

This is a very useful library to generate time series. It has all kinds of DGPs that you can mix and match and create authentic synthetic time series.

Important note

For the exact code and usage, please refer to the associated Jupyter notebooks.

Let's see how we can use a sinusoidal function to create cyclicity. There is a helpful function in TimeSynth called generate_timeseries that helps us combine signals and generate time series. Have a look at the following code snippet:

#Sinusoidal Signal with Amplitude=1.5 & Frequency=0.25
signal_1 =ts.signals.Sinusoidal(amplitude=1.5, frequency=0.25)
#Sinusoidal Signal with Amplitude=1 & Frequency=0. 5
signal_2 = ts.signals.Sinusoidal(amplitude=1, frequency=0.5)
#Generating the time series
samples_1, regular_time_samples, signals_1, errors_1 = generate_timeseries(signal=signal_1)
samples_2, regular_time_samples, signals_2, errors_2 = generate_timeseries(signal=signal_2)
plot_time_series(regular_time_samples, 
                 [samples_1, samples_2], 
                 "Sinusoidal Waves", 
                 legends=["Amplitude = 1.5 | Frequency = 0.25", "Amplitude = 1 | Frequency = 0.5"])

Here is the output:

Figure 1.5 – Sinusoidal waves

Figure 1.5 – Sinusoidal waves

Note the two sinusoidal waves are different with respect to the frequency (how fast the time series crosses zero) and amplitude (how far away from zero the time series travels).

TimeSynth also has another signal called PseudoPeriodic. This is like the Sinusoidal class, but the frequency and amplitude itself has some stochasticity. We can see in the following code snippet that this is more realistic than the vanilla sine and cosine waves from the Sinusoidal class:

# PseudoPeriodic signal with Amplitude=1 & Frequency=0.25
signal = ts.signals.PseudoPeriodic(amplitude=1, frequency=0.25)
#Generating Timeseries
samples, regular_time_samples, signals, errors = generate_timeseries(signal=signal)
plot_time_series(regular_time_samples, 
                 samples, 
                 "Pseudo Periodic")

Here is the output:

Figure 1.6 – Pseudo-periodic signal

Figure 1.6 – Pseudo-periodic signal

Autoregressive signals

Another very popular signal in the real world is an autoregressive (AR) signal. We will go into this in more detail in Chapter 4, Setting a Strong Baseline Forecast, but for now, an AR signal refers to when the value of a time series for the current timestep is dependent on the values of the time series in the previous timesteps. This serial correlation is a key property of the AR signal, and it is parametrized by a few parameters, outlined as follows:

  • Order of serial correlation—or, in other words, the number of previous timesteps the signal is dependent on
  • Coefficients to combine the previous timesteps

Let's see how we can generate an AR signal and see what it looks like, as follows:

# Autoregressive signal with parameters 1.5 and -0.75
# y(t) = 1.5*y(t-1) - 0.75*y(t-2)
signal=ts.signals.AutoRegressive(ar_param=[1.5, -0.75])
#Generate Timeseries
samples, regular_time_samples, signals, errors = generate_timeseries(signal=signal)
plot_time_series(regular_time_samples, 
                 samples, 
                 "Auto Regressive")

Here is the output:

Figure 1.7 – AR signal

Figure 1.7 – AR signal

Mix and match

There are many more components you can use to create your DGP and thereby generate a time series, but let's quickly look at how we can combine the components we have already seen to generate a realistic time series.

Let's use a pseudo-periodic signal with white noise and combine it with an AR signal, as follows:

#Generating Pseudo Periodic Signal
pseudo_samples, regular_time_samples, _, _ = generate_timeseries(signal=ts.signals.PseudoPeriodic(amplitude=1, frequency=0.25), noise=ts.noise.GaussianNoise(std=0.3))
# Generating an Autoregressive Signal
ar_samples, regular_time_samples, _, _ = generate_timeseries(signal=ts.signals.AutoRegressive(ar_param=[1.5, -0.75]))
# Combining the two signals using a mathematical equation
ts = pseudo_samples*2+ar_samples
plot_time_series(regular_time_samples, 
                 ts, 
                 "Pseudo Periodic with AutoRegression and White Noise")

Here is the output:

Figure 1.8 – Pseudo-periodic signal with AR and white noise

Figure 1.8 – Pseudo-periodic signal with AR and white noise

Stationary and non-stationary time series

In time series, stationarity is of great significance and is a key assumption in many modeling approaches. Ironically, many (if not most) real-world time series are non-stationary. So, let's understand what a stationary time series is from a layman's point of view.

There are multiple ways to look at stationarity, but one of the clearest and most intuitive ways is to think of the probability distribution or the data distribution of a time series. We call a time series stationary when the probability distribution remains the same at every point in time. In other words, if you pick different windows in time, the data distribution across all those windows should be the same.

A standard Gaussian distribution is defined by two parameters—the mean and the standard deviation. So, there are two ways the stationarity assumption can be broken, as outlined here:

  • Change in mean over time
  • Change in variance over time

Let's look at these assumptions in detail and understand them better.

Change in mean over time

This is the most popular way a non-stationary time series presents itself. If there is an upward/downward trend in the time series, the mean across two windows of time would not be the same.

Another way non-stationarity manifests itself is in the form of seasonality. Suppose we are looking at the time series of average temperature measurements in a month for the last 5 years. From our experience, we know that temperature peaks during summer and falls in winter. So, when we take the mean temperature of winter and mean temperature of summer, they will be different.

Let's generate a time series with trend and seasonality and see how it manifests, as follows:

# Sinusoidal Signal with Amplitude=1 & Frequency=0.25
signal=ts.signals.Sinusoidal(amplitude=1, frequency=0.25)
# White Noise with standard deviation = 0.3
noise=ts.noise.GaussianNoise(std=0.3)
# Generate the time series
sinusoidal_samples, regular_time_samples, _, _ = generate_timeseries(signal=signal, noise=noise)
# Regular_time_samples is a linear increasing time axis and can be used as a trend
trend = regular_time_samples*0.4
# Combining the signal and trend
ts = sinusoidal_samples+trend
plot_time_series(regular_time_samples, 
                 ts, 
                 "Sinusoidal with Trend and White Noise")

Here is the output:

Figure 1.9 – Sinusoidal signal with trend and white noise

Figure 1.9 – Sinusoidal signal with trend and white noise

If you examine the time series in Figure 1.9, you will be able to see a definite trend and the seasonality, which together make the mean of the data distribution change wildly across different windows of time.

Change in variance over time

Non-stationarity can also present itself in the fluctuating variance of a time series. If the time series starts off with low variance and as time progresses, the variance keeps getting bigger and bigger, we have a non-stationary time series. In statistics, there is a scary name for this phenomenon—heteroscedasticity.

This book just tries to give you intuition about stationary versus non-stationary time series. There is a lot of statistical theory and depth in this discussion that we are skipping over to keep our focus on the practical aspects of time series.

Armed with the mental model of the DGP, we are at the right place to think about another important question: What can we forecast?

What can we forecast?

Before we move ahead, there is another aspect of time series forecasting that we have to understand—the predictability of a time series. The most basic assumption when we forecast a time series is that the future depends on the past. But not all time series are equally predictable.

Let's take a look at a few examples and try to rank these in order of predictability (from easiest to hardest), as follows:

  • High tide next Monday
  • Lottery numbers next Sunday
  • The stock price of Tesla next Friday

Intuitively, it is very easy for us to rank them. High tide next Monday is going to be the easiest to predict because it is so predictable, the lottery numbers are going to be very hard to predict because these are pretty much random, and the stock price of Tesla next Friday is going to be difficult to predict, but not impossible.

Note

However, for people thinking that they can forecast stock prices with the awesome techniques covered in the book and get rich, that won't happen. Although it is worthy of a lengthy discussion, we can summarize the key points in a short paragraph.

Share prices are not a function of their past values but an anticipation of their future values, and this thereby violates our first assumption while forecasting. And if that is not bad enough, financial stock prices typically have a very low signal-to-noise ratio. The final wrench in the process is the efficient-market hypothesis (EMH). This seemingly innocent hypothesis proclaims that all known information about a stock price is already factored into the price of the stock. The implication of the hypothesis is that if you can forecast accurately, many others will also be able to do that, and thereby the market price of the stock already reflects the change in price that this forecast brought about.

Coming back to the topic at hand—predictability—three main factors form a mental model for this, as follows:

  • Understanding the DGP: The better you understand the DGP, the higher the predictability of a time series.
  • Amount of data: The more data you have, the better your predictability is.
  • Adequately repeating pattern: For any mathematical model to work well, there should be an adequately repeating pattern in your time series. The more repeatable the pattern is, the better your predictability is.

Even though you have a mental model of how to think about predictability, we will look at more concrete ways of assessing the predictability of time series in Chapter 3, Analyzing and Visualizing Time Series Data, but the key takeaway is that not all time series are equally predictable.

In order to fully follow the discussion in the coming chapters, we need to establish a standard notation and get updated on terminology that is specific to time series analysis.

Forecasting terminology

There are a few terminologies that will help you follow the book as well as other literature on time series. These are described in more detail here:

  • Forecasting

Forecasting is the prediction of future values of a time series using the known past values of the time series and/or some other related variables. This is very similar to prediction in ML where we use a model to predict unseen data.

  • Multivariate forecasting

Multivariate time series consist of more than one time series variable that is not only dependent on its past values but also has some dependency on the other variables. For example, a set of macroeconomic indicators such as gross domestic product (GDP), inflation, and so on of a particular country can be considered as a multivariate time series. The aim of multivariate forecasting is to come up with a model that captures the interrelationship between the different variables along with its relationship with its past and forecast all the time series together in the future.

  • Explanatory forecasting

In addition to the past values of a time series, we might use some other information to predict the future values of a time series. For example, for predicting retail store sales, information regarding promotional offers (both historical and future ones) is usually helpful. This type of forecasting, which uses information other than its own history, is called explanatory forecasting.

  • Backtesting

Setting aside a validation set from your training data to evaluate your models is a practice that is common in the ML world. Backtesting is the time series equivalent of validation, whereby you use the history to evaluate a trained model. We will cover the different ways of doing validation and cross-validation for time series data later.

  • In-sample and out-sample

Again, drawing parallels with ML, in-sample refers to training data and out-sample refers to unseen or testing data. When you hear in-sample metrics, this is referring to metrics calculated on training data, and out-sample metrics is referring to metrics calculated on testing data.

  • Exogenous and endogenous variables

Exogenous variables are parallel time series variables that are not modeled directly for output but used to help us model the time series that we are interested in. Typically, exogenous variables are not affected by other variables in the system. Endogenous variables are variables that are affected by other variables in the system. A purely endogenous variable is a variable that is entirely dependent on the other variables in the system. Relaxing the strict assumptions a bit, we can consider the target variable as the endogenous variable and the explanatory regressors we include in the model as exogenous variables.

  • Forecast combination

Forecast combinations in the time series world are similar to ensembling from the ML world. It is a process by which we combine multiple forecasts by using some function, either learned or heuristic-based, such as a simple average of three forecast models.

There are a lot more terms specific to time series, some of which we will be covering throughout the book. But to start with a basic familiarity in the field, these terms should be enough.

Summary

We had our first dip into time series as we understood the different types of time series, looked at how a DGP generates a time series, and saw how we can think about the important question: How well can we forecast a time series? We also had a quick review of the terminology and notation required to understand the rest of the book. In the next chapter, we will be getting our hands dirty and will learn how to work with time series data, how to preprocess a time series, how to handle missing data and outliers, and so on. If you have not set up the environment yet, take a break and put some time into doing that.

Further reading

  • A Survey on Principles, Models and Methods for Learning from Irregularly Sampled Time Series: From Discretization to Attention and Invariance by S.N. Shukla and B.M. Marlin (2020): https://arxiv.org/abs/2012.00168
  • Learning from Irregularly-Sampled Time Series: A Missing Data Perspective by S.C. Li and B.M. Marlin (2020), ICML: https://arxiv.org/abs/2008.07599
Left arrow icon Right arrow icon
Download code icon Download Code

Key benefits

  • Explore industry-tested machine learning techniques used to forecast millions of time series
  • Get started with the revolutionary paradigm of global forecasting models
  • Get to grips with new concepts by applying them to real-world datasets of energy forecasting

Description

We live in a serendipitous era where the explosion in the quantum of data collected and a renewed interest in data-driven techniques such as machine learning (ML), has changed the landscape of analytics, and with it, time series forecasting. This book, filled with industry-tested tips and tricks, takes you beyond commonly used classical statistical methods such as ARIMA and introduces to you the latest techniques from the world of ML. This is a comprehensive guide to analyzing, visualizing, and creating state-of-the-art forecasting systems, complete with common topics such as ML and deep learning (DL) as well as rarely touched-upon topics such as global forecasting models, cross-validation strategies, and forecast metrics. You’ll begin by exploring the basics of data handling, data visualization, and classical statistical methods before moving on to ML and DL models for time series forecasting. This book takes you on a hands-on journey in which you’ll develop state-of-the-art ML (linear regression to gradient-boosted trees) and DL (feed-forward neural networks, LSTMs, and transformers) models on a real-world dataset along with exploring practical topics such as interpretability. By the end of this book, you’ll be able to build world-class time series forecasting systems and tackle problems in the real world.

Who is this book for?

The book is for data scientists, data analysts, machine learning engineers, and Python developers who want to build industry-ready time series models. Since the book explains most concepts from the ground up, basic proficiency in Python is all you need. Prior understanding of machine learning or forecasting will help speed up your learning. For experienced machine learning and forecasting practitioners, this book has a lot to offer in terms of advanced techniques and traversing the latest research frontiers in time series forecasting.

What you will learn

  • Find out how to manipulate and visualize time series data like a pro
  • Set strong baselines with popular models such as ARIMA
  • Discover how time series forecasting can be cast as regression
  • Engineer features for machine learning models for forecasting
  • Explore the exciting world of ensembling and stacking models
  • Get to grips with the global forecasting paradigm
  • Understand and apply state-of-the-art DL models such as N-BEATS and Autoformer
  • Explore multi-step forecasting and cross-validation strategies
Estimated delivery fee Deliver to Hungary

Premium delivery 7 - 10 business days

€25.95
(Includes tracking information)

Product Details

Country selected
Publication date, Length, Edition, Language, ISBN-13
Publication date : Nov 24, 2022
Length: 552 pages
Edition : 1st
Language : English
ISBN-13 : 9781803246802
Category :
Languages :
Concepts :

What do you get with Print?

Product feature icon Instant access to your digital eBook copy whilst your Print order is Shipped
Product feature icon Paperback book shipped to your preferred address
Product feature icon Download this book in EPUB and PDF formats
Product feature icon Access this title in our online reader with advanced features
Product feature icon DRM FREE - Read whenever, wherever and however you want
Product feature icon AI Assistant (beta) to help accelerate your learning
OR
Modal Close icon
Payment Processing...
tick Completed

Shipping Address

Billing Address

Shipping Methods
Estimated delivery fee Deliver to Hungary

Premium delivery 7 - 10 business days

€25.95
(Includes tracking information)

Product Details

Publication date : Nov 24, 2022
Length: 552 pages
Edition : 1st
Language : English
ISBN-13 : 9781803246802
Category :
Languages :
Concepts :

Packt Subscriptions

See our plans and pricing
Modal Close icon
€18.99 billed monthly
Feature tick icon Unlimited access to Packt's library of 7,000+ practical books and videos
Feature tick icon Constantly refreshed with 50+ new titles a month
Feature tick icon Exclusive Early access to books as they're written
Feature tick icon Solve problems while you work with advanced search and reference features
Feature tick icon Offline reading on the mobile app
Feature tick icon Simple pricing, no contract
€189.99 billed annually
Feature tick icon Unlimited access to Packt's library of 7,000+ practical books and videos
Feature tick icon Constantly refreshed with 50+ new titles a month
Feature tick icon Exclusive Early access to books as they're written
Feature tick icon Solve problems while you work with advanced search and reference features
Feature tick icon Offline reading on the mobile app
Feature tick icon Choose a DRM-free eBook or Video every month to keep
Feature tick icon PLUS own as many other DRM-free eBooks or Videos as you like for just €5 each
Feature tick icon Exclusive print discounts
€264.99 billed in 18 months
Feature tick icon Unlimited access to Packt's library of 7,000+ practical books and videos
Feature tick icon Constantly refreshed with 50+ new titles a month
Feature tick icon Exclusive Early access to books as they're written
Feature tick icon Solve problems while you work with advanced search and reference features
Feature tick icon Offline reading on the mobile app
Feature tick icon Choose a DRM-free eBook or Video every month to keep
Feature tick icon PLUS own as many other DRM-free eBooks or Videos as you like for just €5 each
Feature tick icon Exclusive print discounts

Frequently bought together


Stars icon
Total 120.97
Machine Learning with PyTorch and Scikit-Learn
€41.99
Modern Time Series Forecasting with Python
€39.99
Time Series Analysis with Python Cookbook
€38.99
Total 120.97 Stars icon
Banner background image

Table of Contents

25 Chapters
Part 1 – Getting Familiar with Time Series Chevron down icon Chevron up icon
Chapter 1: Introducing Time Series Chevron down icon Chevron up icon
Chapter 2: Acquiring and Processing Time Series Data Chevron down icon Chevron up icon
Chapter 3: Analyzing and Visualizing Time Series Data Chevron down icon Chevron up icon
Chapter 4: Setting a Strong Baseline Forecast Chevron down icon Chevron up icon
Part 2 – Machine Learning for Time Series Chevron down icon Chevron up icon
Chapter 5: Time Series Forecasting as Regression Chevron down icon Chevron up icon
Chapter 6: Feature Engineering for Time Series Forecasting Chevron down icon Chevron up icon
Chapter 7: Target Transformations for Time Series Forecasting Chevron down icon Chevron up icon
Chapter 8: Forecasting Time Series with Machine Learning Models Chevron down icon Chevron up icon
Chapter 9: Ensembling and Stacking Chevron down icon Chevron up icon
Chapter 10: Global Forecasting Models Chevron down icon Chevron up icon
Part 3 – Deep Learning for Time Series Chevron down icon Chevron up icon
Chapter 11: Introduction to Deep Learning Chevron down icon Chevron up icon
Chapter 12: Building Blocks of Deep Learning for Time Series Chevron down icon Chevron up icon
Chapter 13: Common Modeling Patterns for Time Series Chevron down icon Chevron up icon
Chapter 14: Attention and Transformers for Time Series Chevron down icon Chevron up icon
Chapter 15: Strategies for Global Deep Learning Forecasting Models Chevron down icon Chevron up icon
Chapter 16: Specialized Deep Learning Architectures for Forecasting Chevron down icon Chevron up icon
Part 4 – Mechanics of Forecasting Chevron down icon Chevron up icon
Chapter 17: Multi-Step Forecasting Chevron down icon Chevron up icon
Chapter 18: Evaluating Forecasts – Forecast Metrics Chevron down icon Chevron up icon
Chapter 19: Evaluating Forecasts – Validation Strategies Chevron down icon Chevron up icon
Index Chevron down icon Chevron up icon
Other Books You May Enjoy Chevron down icon Chevron up icon

Customer reviews

Top Reviews
Rating distribution
Full star icon Full star icon Full star icon Full star icon Half star icon 4.2
(30 Ratings)
5 star 70%
4 star 10%
3 star 0%
2 star 10%
1 star 10%
Filter icon Filter
Top Reviews

Filter reviews by




Machiel Kruger Feb 22, 2024
Full star icon Full star icon Full star icon Full star icon Full star icon 5
Feefo Verified review Feefo
Archana Dec 13, 2022
Full star icon Full star icon Full star icon Full star icon Full star icon 5
This book explores everything from basics of time series to how it can be implemented in using univariate, multivariate and deeplearning algorithms along with the transformations required for implementation.It mainly helps us in the thought process of forecasting and how it can be done efficiently .thanks a lot for the simplistic and elegant explanation.must read for time series enthusiasts.
Amazon Verified review Amazon
Kumar A. Dec 02, 2022
Full star icon Full star icon Full star icon Full star icon Full star icon 5
It covers all the aspects of modern time series forecasting. The worked examples are easy to understand and explains the concepts well.This book will help practitioners who will be working with real world time series forecasting problems. Candidates will also find it useful for interview preparations in this field.
Amazon Verified review Amazon
Antra Tripathi Dec 21, 2022
Full star icon Full star icon Full star icon Full star icon Full star icon 5
This book is a one-stop for holistic learning on time series. Very well-articulated in a simple yet engaging manner. For data enthusiasts who are beginning their career in machine learning, this book is an absolute read as it covers all the essential and key aspects to build up your expertise on time series ground up. For seasoned professionals, it provides a guide to further incorporate deep learning strategies to make your time series modelling better.Key aspects of the book:1.) I really like how the book is been compartmentalized into four parts, beginning from a simple introduction to time series to using deep learning architecture for the same.2.) The fact that the content for each sub-sections/ sub-headings in the chapters are supported with mathematical representations, graphs, flow diagrams, tables, pictures, and code snippets makes it engaging and interesting to follow through.3.) Each chapter has an exhaustive list of references and a bonus reading section which lists research papers, journals, and articles from curated repositories like ACM, MIT, Stanford, IEEE, etc.4.) The book also covers modelling strategy using the open-source library 'Py Torch Forecasting ' in a self-containing and self-explanatory way, supported with detailed explanations and documented code snippets. So even if you are new to using Py Torch, it won't be difficult to follow the content of the book.As a data science professional, who recently finished a master's in machine learning, I found this book really useful for both professional and academic purposes. I really enjoyed reading specialized deep learning architecture for forecasting such as Neural Basis Expansion for Interpretable TS Forecasting (N-BEATSx) and Temporal Fusion Transformers (TFT) followed by Mechanics of multistep forecasting and validation strategies. I definitely see myself implementing these learnings in my work.KUDOS to the author Manu for such excellent encapsulation of the topic with his domain expertise! Happy Forecasting!
Amazon Verified review Amazon
Faris Jul 06, 2023
Full star icon Full star icon Full star icon Full star icon Full star icon 5
Well written, explainations are detailed enough to get you where you need to go.
Amazon Verified review Amazon
Get free access to Packt library with over 7500+ books and video courses for 7 days!
Start Free Trial

FAQs

What is the delivery time and cost of print book? Chevron down icon Chevron up icon

Shipping Details

USA:

'

Economy: Delivery to most addresses in the US within 10-15 business days

Premium: Trackable Delivery to most addresses in the US within 3-8 business days

UK:

Economy: Delivery to most addresses in the U.K. within 7-9 business days.
Shipments are not trackable

Premium: Trackable delivery to most addresses in the U.K. within 3-4 business days!
Add one extra business day for deliveries to Northern Ireland and Scottish Highlands and islands

EU:

Premium: Trackable delivery to most EU destinations within 4-9 business days.

Australia:

Economy: Can deliver to P. O. Boxes and private residences.
Trackable service with delivery to addresses in Australia only.
Delivery time ranges from 7-9 business days for VIC and 8-10 business days for Interstate metro
Delivery time is up to 15 business days for remote areas of WA, NT & QLD.

Premium: Delivery to addresses in Australia only
Trackable delivery to most P. O. Boxes and private residences in Australia within 4-5 days based on the distance to a destination following dispatch.

India:

Premium: Delivery to most Indian addresses within 5-6 business days

Rest of the World:

Premium: Countries in the American continent: Trackable delivery to most countries within 4-7 business days

Asia:

Premium: Delivery to most Asian addresses within 5-9 business days

Disclaimer:
All orders received before 5 PM U.K time would start printing from the next business day. So the estimated delivery times start from the next day as well. Orders received after 5 PM U.K time (in our internal systems) on a business day or anytime on the weekend will begin printing the second to next business day. For example, an order placed at 11 AM today will begin printing tomorrow, whereas an order placed at 9 PM tonight will begin printing the day after tomorrow.


Unfortunately, due to several restrictions, we are unable to ship to the following countries:

  1. Afghanistan
  2. American Samoa
  3. Belarus
  4. Brunei Darussalam
  5. Central African Republic
  6. The Democratic Republic of Congo
  7. Eritrea
  8. Guinea-bissau
  9. Iran
  10. Lebanon
  11. Libiya Arab Jamahriya
  12. Somalia
  13. Sudan
  14. Russian Federation
  15. Syrian Arab Republic
  16. Ukraine
  17. Venezuela
What is custom duty/charge? Chevron down icon Chevron up icon

Customs duty are charges levied on goods when they cross international borders. It is a tax that is imposed on imported goods. These duties are charged by special authorities and bodies created by local governments and are meant to protect local industries, economies, and businesses.

Do I have to pay customs charges for the print book order? Chevron down icon Chevron up icon

The orders shipped to the countries that are listed under EU27 will not bear custom charges. They are paid by Packt as part of the order.

List of EU27 countries: www.gov.uk/eu-eea:

A custom duty or localized taxes may be applicable on the shipment and would be charged by the recipient country outside of the EU27 which should be paid by the customer and these duties are not included in the shipping charges been charged on the order.

How do I know my custom duty charges? Chevron down icon Chevron up icon

The amount of duty payable varies greatly depending on the imported goods, the country of origin and several other factors like the total invoice amount or dimensions like weight, and other such criteria applicable in your country.

For example:

  • If you live in Mexico, and the declared value of your ordered items is over $ 50, for you to receive a package, you will have to pay additional import tax of 19% which will be $ 9.50 to the courier service.
  • Whereas if you live in Turkey, and the declared value of your ordered items is over € 22, for you to receive a package, you will have to pay additional import tax of 18% which will be € 3.96 to the courier service.
How can I cancel my order? Chevron down icon Chevron up icon

Cancellation Policy for Published Printed Books:

You can cancel any order within 1 hour of placing the order. Simply contact [email protected] with your order details or payment transaction id. If your order has already started the shipment process, we will do our best to stop it. However, if it is already on the way to you then when you receive it, you can contact us at [email protected] using the returns and refund process.

Please understand that Packt Publishing cannot provide refunds or cancel any order except for the cases described in our Return Policy (i.e. Packt Publishing agrees to replace your printed book because it arrives damaged or material defect in book), Packt Publishing will not accept returns.

What is your returns and refunds policy? Chevron down icon Chevron up icon

Return Policy:

We want you to be happy with your purchase from Packtpub.com. We will not hassle you with returning print books to us. If the print book you receive from us is incorrect, damaged, doesn't work or is unacceptably late, please contact Customer Relations Team on [email protected] with the order number and issue details as explained below:

  1. If you ordered (eBook, Video or Print Book) incorrectly or accidentally, please contact Customer Relations Team on [email protected] within one hour of placing the order and we will replace/refund you the item cost.
  2. Sadly, if your eBook or Video file is faulty or a fault occurs during the eBook or Video being made available to you, i.e. during download then you should contact Customer Relations Team within 14 days of purchase on [email protected] who will be able to resolve this issue for you.
  3. You will have a choice of replacement or refund of the problem items.(damaged, defective or incorrect)
  4. Once Customer Care Team confirms that you will be refunded, you should receive the refund within 10 to 12 working days.
  5. If you are only requesting a refund of one book from a multiple order, then we will refund you the appropriate single item.
  6. Where the items were shipped under a free shipping offer, there will be no shipping costs to refund.

On the off chance your printed book arrives damaged, with book material defect, contact our Customer Relation Team on [email protected] within 14 days of receipt of the book with appropriate evidence of damage and we will work with you to secure a replacement copy, if necessary. Please note that each printed book you order from us is individually made by Packt's professional book-printing partner which is on a print-on-demand basis.

What tax is charged? Chevron down icon Chevron up icon

Currently, no tax is charged on the purchase of any print book (subject to change based on the laws and regulations). A localized VAT fee is charged only to our European and UK customers on eBooks, Video and subscriptions that they buy. GST is charged to Indian customers for eBooks and video purchases.

What payment methods can I use? Chevron down icon Chevron up icon

You can pay with the following card types:

  1. Visa Debit
  2. Visa Credit
  3. MasterCard
  4. PayPal
What is the delivery time and cost of print books? Chevron down icon Chevron up icon

Shipping Details

USA:

'

Economy: Delivery to most addresses in the US within 10-15 business days

Premium: Trackable Delivery to most addresses in the US within 3-8 business days

UK:

Economy: Delivery to most addresses in the U.K. within 7-9 business days.
Shipments are not trackable

Premium: Trackable delivery to most addresses in the U.K. within 3-4 business days!
Add one extra business day for deliveries to Northern Ireland and Scottish Highlands and islands

EU:

Premium: Trackable delivery to most EU destinations within 4-9 business days.

Australia:

Economy: Can deliver to P. O. Boxes and private residences.
Trackable service with delivery to addresses in Australia only.
Delivery time ranges from 7-9 business days for VIC and 8-10 business days for Interstate metro
Delivery time is up to 15 business days for remote areas of WA, NT & QLD.

Premium: Delivery to addresses in Australia only
Trackable delivery to most P. O. Boxes and private residences in Australia within 4-5 days based on the distance to a destination following dispatch.

India:

Premium: Delivery to most Indian addresses within 5-6 business days

Rest of the World:

Premium: Countries in the American continent: Trackable delivery to most countries within 4-7 business days

Asia:

Premium: Delivery to most Asian addresses within 5-9 business days

Disclaimer:
All orders received before 5 PM U.K time would start printing from the next business day. So the estimated delivery times start from the next day as well. Orders received after 5 PM U.K time (in our internal systems) on a business day or anytime on the weekend will begin printing the second to next business day. For example, an order placed at 11 AM today will begin printing tomorrow, whereas an order placed at 9 PM tonight will begin printing the day after tomorrow.


Unfortunately, due to several restrictions, we are unable to ship to the following countries:

  1. Afghanistan
  2. American Samoa
  3. Belarus
  4. Brunei Darussalam
  5. Central African Republic
  6. The Democratic Republic of Congo
  7. Eritrea
  8. Guinea-bissau
  9. Iran
  10. Lebanon
  11. Libiya Arab Jamahriya
  12. Somalia
  13. Sudan
  14. Russian Federation
  15. Syrian Arab Republic
  16. Ukraine
  17. Venezuela