This document provides an overview and agenda for a 3-day training course on seasonal adjustment and using the JDemetra+ software. Day 1 introduces time series analysis concepts like seasonality and decomposition models. It covers the reasons for seasonal adjustment and the step-by-step procedure. The afternoon is spent getting familiar with the JDemetra+ software. Day 2 focuses on identifying and adjusting for outliers and calendar effects. Day 3 includes exercises adjusting real economic data series and demonstrations by participants.
Forecasting techniques, time series analysisSATISH KUMAR
This document discusses forecasting techniques and time series analysis. It defines forecasting as the estimation or prediction of future outcomes, trends, or behavior through the use of statistics. The document outlines several key points:
- It describes the meaning, definition, features, process, importance, advantages, and limitations of forecasting.
- It discusses various qualitative and quantitative forecasting methods including regression analysis, business barometers, input/output analysis, surveys, and time series analysis.
- It explains the components of time series analysis including secular trends, seasonal variations, cyclical variations, and irregular variations.
- It provides examples of each type of variation and discusses their importance for time series forecasting.
This document discusses time series analysis and its key components. It begins by defining a time series as a sequence of data points measured over successive time periods. The four main components of a time series are identified as: 1) Trend - the long-term pattern of increase or decrease, 2) Seasonal variations - repeating patterns over 12 months, 3) Cyclical variations - fluctuations lasting more than a year, and 4) Irregular variations - unpredictable fluctuations. Two common methods for measuring trends are introduced as the moving average method and least squares method. Formulas and examples are provided for calculating trend values using these techniques.
The document lists the names of several individuals and thanks Dr. Vandana Sarin Walia for providing an opportunity to apply knowledge through a project. It states the project allowed practical experience and guidance was provided to complete the project. It expresses hope the project met expectations.
This document provides an overview of time series analysis. It defines a time series as numerical data obtained at regular time intervals that occurs in many domains like economics and finance. The goals of time series analysis are to describe, summarize, fit models to, and forecast time series data. Time series are different from other data as observations are not independent. The document discusses the various components of time series including trends, seasonality, cycles, and irregular variations. It provides examples of decomposing time series into these components to better understand the underlying patterns in the data.
This document discusses time series analysis. It defines a time series as values of a variable ordered over time. Examples of time series include climate data, financial data, and demographic data. Time series analysis is important for understanding past behavior, predicting the future, evaluating programs, and facilitating comparisons. Components of a time series include trends, cyclic variations, seasonal variations, and irregular variations. Several methods are discussed for measuring and decomposing these components, including moving averages, least squares, and seasonal indices.
The document discusses time series analysis and its key components. It defines a time series as a set of data points indexed (or listed or graphed) in time order. A time series collects readings of a variable at evenly-spaced periods of time. It notes that time is the independent variable while the data is the dependent variable. The document outlines the main components of time series as trends, seasonal variations, cyclical variations, and irregular variations. It provides examples and discusses methods for measuring each component, including free hand curve, semi-average, moving average, and least squares. The purposes and importance of time series analysis are also highlighted.
The document discusses different components of time series data including trends, seasonal variations, cyclical fluctuations, and irregular components. It explains that a time series is a collection of observations made over time and can be decomposed into secular trends, periodic changes, and random components. Various methods for measuring trends in time series data are also presented such as graphic, semi-average, curve fitting, and moving average methods.
The document provides an overview of time series analysis. It defines a time series as numerical data obtained at regular time intervals that can be analyzed to describe patterns, fit models, and make forecasts. Time series are different from other data because observations are not independent. The document discusses the key components of time series, including trend, seasonal variation, cyclical variation, and irregular variation. It also covers techniques for smoothing time series data, such as moving averages, and measuring seasonal effects through seasonal indices. The overall goal of time series analysis is to understand and separate out the different variations in a time series to better predict future trends.
Forecasting techniques, time series analysisSATISH KUMAR
This document discusses forecasting techniques and time series analysis. It defines forecasting as the estimation or prediction of future outcomes, trends, or behavior through the use of statistics. The document outlines several key points:
- It describes the meaning, definition, features, process, importance, advantages, and limitations of forecasting.
- It discusses various qualitative and quantitative forecasting methods including regression analysis, business barometers, input/output analysis, surveys, and time series analysis.
- It explains the components of time series analysis including secular trends, seasonal variations, cyclical variations, and irregular variations.
- It provides examples of each type of variation and discusses their importance for time series forecasting.
This document discusses time series analysis and its key components. It begins by defining a time series as a sequence of data points measured over successive time periods. The four main components of a time series are identified as: 1) Trend - the long-term pattern of increase or decrease, 2) Seasonal variations - repeating patterns over 12 months, 3) Cyclical variations - fluctuations lasting more than a year, and 4) Irregular variations - unpredictable fluctuations. Two common methods for measuring trends are introduced as the moving average method and least squares method. Formulas and examples are provided for calculating trend values using these techniques.
The document lists the names of several individuals and thanks Dr. Vandana Sarin Walia for providing an opportunity to apply knowledge through a project. It states the project allowed practical experience and guidance was provided to complete the project. It expresses hope the project met expectations.
This document provides an overview of time series analysis. It defines a time series as numerical data obtained at regular time intervals that occurs in many domains like economics and finance. The goals of time series analysis are to describe, summarize, fit models to, and forecast time series data. Time series are different from other data as observations are not independent. The document discusses the various components of time series including trends, seasonality, cycles, and irregular variations. It provides examples of decomposing time series into these components to better understand the underlying patterns in the data.
This document discusses time series analysis. It defines a time series as values of a variable ordered over time. Examples of time series include climate data, financial data, and demographic data. Time series analysis is important for understanding past behavior, predicting the future, evaluating programs, and facilitating comparisons. Components of a time series include trends, cyclic variations, seasonal variations, and irregular variations. Several methods are discussed for measuring and decomposing these components, including moving averages, least squares, and seasonal indices.
The document discusses time series analysis and its key components. It defines a time series as a set of data points indexed (or listed or graphed) in time order. A time series collects readings of a variable at evenly-spaced periods of time. It notes that time is the independent variable while the data is the dependent variable. The document outlines the main components of time series as trends, seasonal variations, cyclical variations, and irregular variations. It provides examples and discusses methods for measuring each component, including free hand curve, semi-average, moving average, and least squares. The purposes and importance of time series analysis are also highlighted.
The document discusses different components of time series data including trends, seasonal variations, cyclical fluctuations, and irregular components. It explains that a time series is a collection of observations made over time and can be decomposed into secular trends, periodic changes, and random components. Various methods for measuring trends in time series data are also presented such as graphic, semi-average, curve fitting, and moving average methods.
The document provides an overview of time series analysis. It defines a time series as numerical data obtained at regular time intervals that can be analyzed to describe patterns, fit models, and make forecasts. Time series are different from other data because observations are not independent. The document discusses the key components of time series, including trend, seasonal variation, cyclical variation, and irregular variation. It also covers techniques for smoothing time series data, such as moving averages, and measuring seasonal effects through seasonal indices. The overall goal of time series analysis is to understand and separate out the different variations in a time series to better predict future trends.
Statistical estimators are functions used to estimate unknown parameters of a theoretical probability distribution based on random variable observations. There are two main types of estimators: point estimators that provide a single value and interval estimators that provide a range of values within which the parameter is estimated to lie. Key properties for ideal estimators include being unbiased, consistent, sufficient, and having minimum variance. Examples are provided to illustrate calculating confidence intervals for population means based on sample statistics.
This document provides an overview of time series analysis and forecasting techniques. It discusses key concepts such as stationary and non-stationary time series, additive and multiplicative models, smoothing methods like moving averages and exponential smoothing, autoregressive (AR), moving average (MA) and autoregressive integrated moving average (ARIMA) models. The document uses examples to illustrate how to identify patterns in time series data and select appropriate models for description, explanation and forecasting of time series.
Time Series Analysis, Components and Application in ForecastingSundar B N
Time series analysis involves analyzing data collected over time. A time series is a set of observations made at regular intervals. There are four main components of a time series: secular trend, seasonal variation, cyclical variation, and irregular variation. Time series analysis has applications in forecasting, such as for economic forecasting, sales forecasting, and stock market analysis. Techniques for time series analysis include Box-Jenkins ARIMA models, Box-Jenkins multivariate models, and Holt-Winters exponential smoothing.
Descriptive statistics is used to describe and summarize key characteristics of a data set. Commonly used measures include central tendency, such as the mean, median, and mode, and measures of dispersion like range, interquartile range, standard deviation, and variance. The mean is the average value calculated by summing all values and dividing by the number of values. The median is the middle value when data is arranged in order. The mode is the most frequently occurring value. Measures of dispersion describe how spread out the data is, such as the difference between highest and lowest values (range) or how close values are to the average (standard deviation).
Trend analysis and time Series Analysis Amna Kouser
Trend analysis uses historical data to predict future movements in stocks. It assumes past performance can indicate future performance when accounting for sector trends, market conditions, and competition. Trend analysis calculates percentage changes over periods of two years or more to identify trends and make short-term, intermediate, and long-term projections. Financial analysts use trend analysis to assess a company's financial health and future performance by examining past performance and current conditions.
This document provides an overview of key concepts in elementary statistics, including:
- Descriptive statistics describes data while inferential statistics allows generalizing from samples to populations.
- Variables can be qualitative like gender or quantitative with numerical values. Data can be nominal, ordinal, interval, or ratio.
- There are various methods for collecting data like random, systematic, and stratified sampling. Studies can also be observational or experimental.
Time series data are observations collected over time on one or more variables. Time series data can be used to analyze problems involving changes over time, such as stock prices, GDP, and exchange rates. Time series data must be stationary, meaning that its statistical properties like mean and variance do not change over time, to avoid spurious regressions. Non-stationary time series can be transformed to become stationary through differencing, removing trends, or taking logs. Common time series models like ARIMA rely on stationary data.
Survival analysis is a branch of statistics used to analyze time-to-event data, such as time until death or failure. It estimates the probability that an individual survives past a given time and compares survival times between groups. Objectives include estimating survival probabilities, comparing survival between groups, and assessing how covariates relate to survival time. Survival data can be complete or censored. The Kaplan-Meier estimator is used to estimate survival when there is censoring. The log-rank test compares survival curves between treatment groups, and Cox regression incorporates covariates to predict survival probabilities.
This document provides an overview of time series analysis and properties of time series data. It discusses key concepts such as:
- Time series data consisting of successive observations made over time at regular intervals.
- Examples of time series include stock prices, interest rates, GDP, and other economic indicators measured over time.
- Properties of time series data including non-stationarity, autocorrelation, and seasonal patterns.
- Components of time series including trends, seasonal variations, cyclical patterns, and irregular fluctuations.
- The importance of testing for and addressing non-stationarity through differencing or other transformations before modeling and forecasting time series data.
This document provides an overview of time series analysis and its key components. It discusses that a time series is a set of data measured at successive times joined together by time order. The main components of a time series are trends, seasonal variations, cyclical variations, and irregular variations. Time series analysis is important for business forecasting, understanding past behavior, and facilitating comparison. There are two main mathematical models used - the additive model which assumes data is the sum of its components, and the multiplicative model which assumes data is the product of its components. Decomposition of a time series involves discovering, measuring, and isolating these different components.
This document defines time series and its components. A time series is a set of observations recorded over successive time intervals. It has four main components: trend, seasonality, cycles, and irregular variations. Trend refers to the overall increasing or decreasing tendency over time. Seasonality refers to predictable changes that occur around the same time each year. Cycles have periods longer than a year. Irregular variations are random fluctuations. The document also discusses methods for analyzing time series components including additive, multiplicative, and mixed models.
This document provides an overview of statistical inference. It discusses descriptive statistics, which summarize data, and inferential statistics, which are used to generalize from samples to populations. Key concepts covered include estimation, hypothesis testing, parameters, statistics, confidence intervals, significance levels, types of errors. Examples are given of how to calculate confidence intervals for means and proportions and how to perform hypothesis tests using z-tests and t-tests. Steps for conducting hypothesis tests are outlined.
This document discusses factors that influence the selection of data analysis strategies and provides a classification of statistical techniques. It notes that the previous research steps, known data characteristics, statistical technique properties, and researcher background all impact strategy selection. Statistical techniques can be univariate, analyzing single variables, or multivariate, analyzing relationships between multiple variables simultaneously. Multivariate techniques are further classified as dependence techniques, with identifiable dependent and independent variables, or interdependence techniques examining whole variable sets. The document provides examples of common univariate and multivariate techniques.
This document discusses descriptive statistics used in research. It defines descriptive statistics as procedures used to organize, interpret, and communicate numeric data. Key aspects covered include frequency distributions, measures of central tendency (mode, median, mean), measures of variability, bivariate descriptive statistics using contingency tables and correlation, and describing risk to facilitate evidence-based decision making. The overall purpose of descriptive statistics is to synthesize and summarize quantitative data for analysis in research.
This document discusses various forecasting methods including:
- Calculating forecasts using moving averages, weighted moving averages, and exponential smoothing
- Choosing the appropriate forecasting model based on data availability, time horizon, required accuracy, and resources
- Comparing forecast accuracy using metrics like forecast error which measure the difference between actual and forecasted values
1) To understand the underlying structure of Time Series represented by sequence of observations by breaking it down to its components.
2) To fit a mathematical model and proceed to forecast the future.
Power and sample size calculations for survival analysis webinar SlidesnQuery
This webinar presentation introduced sample size determination for survival analysis. It discussed how to estimate the appropriate sample size, key considerations for survival analysis including expected survival curves and handling dropouts. It demonstrated an example in nQuery software to calculate the sample size needed for a clinical trial to show a risk reduction in progression-free survival between treatment arms. The webinar concluded with plans to further enhance survival analysis capabilities in nQuery and addressed questions from participants.
Time series analysis involves analyzing data collected over time. A time series is a set of data points indexed in time order. The key components of a time series are trends, seasonality, cycles, and irregular variations. Trend refers to the long-term movement of a time series over time. Seasonality refers to periodic fluctuations that occur each year, such as higher sales in winter. Cyclical variations are longer term fluctuations in business cycles. Irregular variations are random, unpredictable fluctuations. Time series analysis is important for forecasting, economic analysis, and business planning. Common methods for analyzing time series components include moving averages, least squares regression, decomposition models, and harmonic analysis.
This document provides an overview of basic statistics concepts. It defines statistics as the science of collecting, presenting, analyzing, and reasonably interpreting data. Descriptive statistics are used to summarize and organize data through methods like tables, graphs, and descriptive values, while inferential statistics allow researchers to make general conclusions about populations based on sample data. Variables can be either categorical or quantitative, and their distributions and presentations are discussed.
This document discusses point and interval estimation. It defines an estimator as a function used to infer an unknown population parameter based on sample data. Point estimation provides a single value, while interval estimation provides a range of values with a certain confidence level, such as 95%. Common point estimators include the sample mean and proportion. Interval estimators account for variability in samples and provide more information than point estimators. The document provides examples of how to construct confidence intervals using point estimates, confidence levels, and standard errors or deviations.
The document provides an overview of time series analysis, including definitions, components, and methods for measuring trends, seasonal variations, cyclical variations, and irregular variations in time series data. It discusses adjusting raw time series data, measuring linear and nonlinear trends, converting annual trends to monthly trends, and different methods for measuring seasonal, cyclical, and irregular variations, including indexes and averages. Examples are provided to illustrate calculating seasonal variations using the monthly average method.
This document provides an overview of time series analysis and the Box-Jenkins methodology. Time series analysis attempts to model observations over time and identify patterns. The goals are to identify the structure of the time series and forecast future values. The Box-Jenkins methodology involves conditioning the data, selecting a model, estimating parameters, and assessing the model. Autocorrelation (ACF) and partial autocorrelation (PACF) plots are used to identify autoregressive (AR), moving average (MA), and autoregressive integrated moving average (ARIMA) models.
Statistical estimators are functions used to estimate unknown parameters of a theoretical probability distribution based on random variable observations. There are two main types of estimators: point estimators that provide a single value and interval estimators that provide a range of values within which the parameter is estimated to lie. Key properties for ideal estimators include being unbiased, consistent, sufficient, and having minimum variance. Examples are provided to illustrate calculating confidence intervals for population means based on sample statistics.
This document provides an overview of time series analysis and forecasting techniques. It discusses key concepts such as stationary and non-stationary time series, additive and multiplicative models, smoothing methods like moving averages and exponential smoothing, autoregressive (AR), moving average (MA) and autoregressive integrated moving average (ARIMA) models. The document uses examples to illustrate how to identify patterns in time series data and select appropriate models for description, explanation and forecasting of time series.
Time Series Analysis, Components and Application in ForecastingSundar B N
Time series analysis involves analyzing data collected over time. A time series is a set of observations made at regular intervals. There are four main components of a time series: secular trend, seasonal variation, cyclical variation, and irregular variation. Time series analysis has applications in forecasting, such as for economic forecasting, sales forecasting, and stock market analysis. Techniques for time series analysis include Box-Jenkins ARIMA models, Box-Jenkins multivariate models, and Holt-Winters exponential smoothing.
Descriptive statistics is used to describe and summarize key characteristics of a data set. Commonly used measures include central tendency, such as the mean, median, and mode, and measures of dispersion like range, interquartile range, standard deviation, and variance. The mean is the average value calculated by summing all values and dividing by the number of values. The median is the middle value when data is arranged in order. The mode is the most frequently occurring value. Measures of dispersion describe how spread out the data is, such as the difference between highest and lowest values (range) or how close values are to the average (standard deviation).
Trend analysis and time Series Analysis Amna Kouser
Trend analysis uses historical data to predict future movements in stocks. It assumes past performance can indicate future performance when accounting for sector trends, market conditions, and competition. Trend analysis calculates percentage changes over periods of two years or more to identify trends and make short-term, intermediate, and long-term projections. Financial analysts use trend analysis to assess a company's financial health and future performance by examining past performance and current conditions.
This document provides an overview of key concepts in elementary statistics, including:
- Descriptive statistics describes data while inferential statistics allows generalizing from samples to populations.
- Variables can be qualitative like gender or quantitative with numerical values. Data can be nominal, ordinal, interval, or ratio.
- There are various methods for collecting data like random, systematic, and stratified sampling. Studies can also be observational or experimental.
Time series data are observations collected over time on one or more variables. Time series data can be used to analyze problems involving changes over time, such as stock prices, GDP, and exchange rates. Time series data must be stationary, meaning that its statistical properties like mean and variance do not change over time, to avoid spurious regressions. Non-stationary time series can be transformed to become stationary through differencing, removing trends, or taking logs. Common time series models like ARIMA rely on stationary data.
Survival analysis is a branch of statistics used to analyze time-to-event data, such as time until death or failure. It estimates the probability that an individual survives past a given time and compares survival times between groups. Objectives include estimating survival probabilities, comparing survival between groups, and assessing how covariates relate to survival time. Survival data can be complete or censored. The Kaplan-Meier estimator is used to estimate survival when there is censoring. The log-rank test compares survival curves between treatment groups, and Cox regression incorporates covariates to predict survival probabilities.
This document provides an overview of time series analysis and properties of time series data. It discusses key concepts such as:
- Time series data consisting of successive observations made over time at regular intervals.
- Examples of time series include stock prices, interest rates, GDP, and other economic indicators measured over time.
- Properties of time series data including non-stationarity, autocorrelation, and seasonal patterns.
- Components of time series including trends, seasonal variations, cyclical patterns, and irregular fluctuations.
- The importance of testing for and addressing non-stationarity through differencing or other transformations before modeling and forecasting time series data.
This document provides an overview of time series analysis and its key components. It discusses that a time series is a set of data measured at successive times joined together by time order. The main components of a time series are trends, seasonal variations, cyclical variations, and irregular variations. Time series analysis is important for business forecasting, understanding past behavior, and facilitating comparison. There are two main mathematical models used - the additive model which assumes data is the sum of its components, and the multiplicative model which assumes data is the product of its components. Decomposition of a time series involves discovering, measuring, and isolating these different components.
This document defines time series and its components. A time series is a set of observations recorded over successive time intervals. It has four main components: trend, seasonality, cycles, and irregular variations. Trend refers to the overall increasing or decreasing tendency over time. Seasonality refers to predictable changes that occur around the same time each year. Cycles have periods longer than a year. Irregular variations are random fluctuations. The document also discusses methods for analyzing time series components including additive, multiplicative, and mixed models.
This document provides an overview of statistical inference. It discusses descriptive statistics, which summarize data, and inferential statistics, which are used to generalize from samples to populations. Key concepts covered include estimation, hypothesis testing, parameters, statistics, confidence intervals, significance levels, types of errors. Examples are given of how to calculate confidence intervals for means and proportions and how to perform hypothesis tests using z-tests and t-tests. Steps for conducting hypothesis tests are outlined.
This document discusses factors that influence the selection of data analysis strategies and provides a classification of statistical techniques. It notes that the previous research steps, known data characteristics, statistical technique properties, and researcher background all impact strategy selection. Statistical techniques can be univariate, analyzing single variables, or multivariate, analyzing relationships between multiple variables simultaneously. Multivariate techniques are further classified as dependence techniques, with identifiable dependent and independent variables, or interdependence techniques examining whole variable sets. The document provides examples of common univariate and multivariate techniques.
This document discusses descriptive statistics used in research. It defines descriptive statistics as procedures used to organize, interpret, and communicate numeric data. Key aspects covered include frequency distributions, measures of central tendency (mode, median, mean), measures of variability, bivariate descriptive statistics using contingency tables and correlation, and describing risk to facilitate evidence-based decision making. The overall purpose of descriptive statistics is to synthesize and summarize quantitative data for analysis in research.
This document discusses various forecasting methods including:
- Calculating forecasts using moving averages, weighted moving averages, and exponential smoothing
- Choosing the appropriate forecasting model based on data availability, time horizon, required accuracy, and resources
- Comparing forecast accuracy using metrics like forecast error which measure the difference between actual and forecasted values
1) To understand the underlying structure of Time Series represented by sequence of observations by breaking it down to its components.
2) To fit a mathematical model and proceed to forecast the future.
Power and sample size calculations for survival analysis webinar SlidesnQuery
This webinar presentation introduced sample size determination for survival analysis. It discussed how to estimate the appropriate sample size, key considerations for survival analysis including expected survival curves and handling dropouts. It demonstrated an example in nQuery software to calculate the sample size needed for a clinical trial to show a risk reduction in progression-free survival between treatment arms. The webinar concluded with plans to further enhance survival analysis capabilities in nQuery and addressed questions from participants.
Time series analysis involves analyzing data collected over time. A time series is a set of data points indexed in time order. The key components of a time series are trends, seasonality, cycles, and irregular variations. Trend refers to the long-term movement of a time series over time. Seasonality refers to periodic fluctuations that occur each year, such as higher sales in winter. Cyclical variations are longer term fluctuations in business cycles. Irregular variations are random, unpredictable fluctuations. Time series analysis is important for forecasting, economic analysis, and business planning. Common methods for analyzing time series components include moving averages, least squares regression, decomposition models, and harmonic analysis.
This document provides an overview of basic statistics concepts. It defines statistics as the science of collecting, presenting, analyzing, and reasonably interpreting data. Descriptive statistics are used to summarize and organize data through methods like tables, graphs, and descriptive values, while inferential statistics allow researchers to make general conclusions about populations based on sample data. Variables can be either categorical or quantitative, and their distributions and presentations are discussed.
This document discusses point and interval estimation. It defines an estimator as a function used to infer an unknown population parameter based on sample data. Point estimation provides a single value, while interval estimation provides a range of values with a certain confidence level, such as 95%. Common point estimators include the sample mean and proportion. Interval estimators account for variability in samples and provide more information than point estimators. The document provides examples of how to construct confidence intervals using point estimates, confidence levels, and standard errors or deviations.
The document provides an overview of time series analysis, including definitions, components, and methods for measuring trends, seasonal variations, cyclical variations, and irregular variations in time series data. It discusses adjusting raw time series data, measuring linear and nonlinear trends, converting annual trends to monthly trends, and different methods for measuring seasonal, cyclical, and irregular variations, including indexes and averages. Examples are provided to illustrate calculating seasonal variations using the monthly average method.
This document provides an overview of time series analysis and the Box-Jenkins methodology. Time series analysis attempts to model observations over time and identify patterns. The goals are to identify the structure of the time series and forecast future values. The Box-Jenkins methodology involves conditioning the data, selecting a model, estimating parameters, and assessing the model. Autocorrelation (ACF) and partial autocorrelation (PACF) plots are used to identify autoregressive (AR), moving average (MA), and autoregressive integrated moving average (ARIMA) models.
This document provides an overview of time series analysis. It defines a time series as numerical data obtained at regular time intervals that occurs in many domains like economics, finance, and environment. Time series data are different from other data as they are not independent and have large sample sizes. The key components of a time series are the trend, seasonal variation, cyclical variation, and irregular/random variation. Decomposition methods are used to separate out these components. Smoothing techniques like moving averages are employed to better understand the overall patterns in time series data. Seasonal indices are calculated to measure the degree to which different seasons vary from each other.
This document provides an introduction to time series forecasting and pattern identification. It begins with examples of things that can be forecasted, such as business metrics, weather, and lottery numbers. The main types of patterns in time series data are then explained: trends (linear, exponential, damped), seasonal, cyclical, and random/irregular. Stationarity and the level component of a time series are also defined. Finally, a flow diagram shows the process for selecting the appropriate forecasting algorithm depending on factors like stationarity, whether the dataset is univariate or multivariate, and what patterns are present. Common algorithms mentioned are Holt-Winters exponential smoothing, ARIMA, and ARIMAX models.
Applied Statistics Chapter 2 Time series (1).pptswamyvivekp
Time series analysis is used to forecast future activity and trends. It involves analyzing trends, seasonal variations, cyclical variations, and irregular fluctuations in data over time. There are several techniques for analyzing trends, including semi-averages, moving averages, least squares regression, and exponential smoothing. Accurately identifying trends can help organizations plan for changes but forecasting also carries risks of uncertainty.
This document defines and discusses key concepts in time series analysis. It begins by defining a time series as a sequence of data points measured at successive time intervals. Time series analysis involves extracting meaningful statistics and characteristics from time series data. Examples of time series include stock prices, exchange rates, GDP, and population growth measured over time. The document outlines properties of time series data including autoregressive, moving average, and seasonal processes. It also discusses the importance of stationarity and describes various tests to check for stationarity like the Dickey-Fuller test. Finally, it lists common univariate time series models like AR, MA, ARMA, ARIMA and SARIMA that are used to analyze time series data.
This document discusses forecasting methods used in production and operations management. It defines forecasting as predicting future values based on historical data. The key types of forecasts discussed are judgmental forecasts using subjective inputs, time series forecasts using historical data patterns, and associative models using explanatory variables. Time series methods covered include simple moving averages, weighted moving averages, and exponential smoothing. Exponential smoothing gives more weight to recent periods to generate forecasts. Quantitative forecasting methods are chosen based on the forecast horizon and data available.
Forecasting is essential for business operations and involves estimating future events and trends. There are two main types of forecasting: quantitative and qualitative. Quantitative forecasting uses historical data and mathematical models, while qualitative forecasting relies on expert opinions. Common quantitative forecasting methods include moving averages, exponential smoothing, and time series models. Moving averages calculate the average demand over a set time period to smooth out fluctuations. Exponential smoothing places more emphasis on recent data by applying weighting factors. Qualitative methods include jury of executive opinion, Delphi method, and consumer surveys. Forecasting allows businesses to better plan operations and prepare for the future.
This document discusses time series analysis and its components. It covers:
- The components of a time series include trends, seasonal variations, cyclical movements, and irregular fluctuations.
- Time series can be analyzed using either an additive or multiplicative model depending on the independence of the components.
- Trends can be measured using a moving average method or least squares method. The document provides examples of both.
- Seasonal variations, forecasting, and deseasonalization are also discussed as part of time series analysis.
Business forecasting and timeseries analysis phpapp02MD ASADUZZAMAN
This document discusses time series analysis and forecasting. It defines forecasting as making predictions about the future based on past data and trends. Business forecasting estimates future sales, expenses, and profits. Time series analysis establishes relationships between variables over time. Key components of time series that influence trends include seasonal, cyclical, secular, and irregular variations. Common forecasting methods mentioned are regression analysis, exponential smoothing, and time series analysis. Measurement of trends can be done using techniques like least squares, moving averages, and semi-averages.
This document discusses trend and seasonal components in time series analysis. It defines trend as the long-term movement in a time series due to underlying economic or socioeconomic factors. Methods for estimating trends include moving averages and least squares. Seasonal components refer to regular fluctuations that occur within the same period each year, such as monthly or quarterly patterns driven by weather, holidays, or other seasonal factors. The document provides examples of trend and seasonal patterns and methods for determining if components are present in a time series, including fitting trend lines using least squares.
Data Science - Part X - Time Series ForecastingDerek Kane
This lecture provides an overview of Time Series forecasting techniques and the process of creating effective forecasts. We will go through some of the popular statistical methods including time series decomposition, exponential smoothing, Holt-Winters, ARIMA, and GLM Models. These topics will be discussed in detail and we will go through the calibration and diagnostics effective time series models on a number of diverse datasets.
Time series modeling involves describing, modeling, and predicting observations over time. Key components of time series include trends, seasonality, and irregular fluctuations. Trend models can be linear, quadratic, or log-linear. Seasonality refers to regular, predictable changes that occur each period, such as changes related to climate, holidays, or calendar effects. The purpose of seasonal adjustment is to decompose a time series into trend, seasonal, calendar, and irregular components to better understand the underlying movements in the data. Both informal graphical methods and formal statistical software can be used to detect seasonality in time series.
This document discusses forecasting techniques based on time series analysis. It defines key concepts like extrapolation, time series components, and analytical indicators. Extrapolation involves projecting past trends and patterns into the future, and can be used to forecast trends, cycles, and causal relationships. Time series data has components like trends, seasonality, cycles, and random variations. Analytical indicators like absolute and percentage changes are used to analyze time series data and make forecasts. The document provides an example of forecasting future demand using average absolute increase and average growth rate.
This document discusses time series analysis. It defines a time series as a set of numerical values of some variable obtained at regular intervals over time. The objectives of time series analysis are to understand the behavior of variables over time and evaluate changes. There are four main components of a time series: trend, which is a long-term movement; cycles, which are medium-term fluctuations; seasonality, which are short-term and regular fluctuations; and irregularity, which are unpredictable short-term changes. Time series can be decomposed using either a multiplicative or additive model to isolate the effects of each component.
This document discusses various methods for analyzing time series data and identifying trends, including:
1. A time series consists of observations measured at regular intervals, and time series analysis aims to identify influencing factors to allow for forecasting.
2. The four main components of variations in time series are secular trends, seasonal variations, cyclical variations, and irregular variations.
3. Secular trends represent long-term growth or decline, while seasonal variations have annual patterns. Cyclical variations have less predictable recurring patterns, and irregular variations occur randomly.
Forecasting is important for businesses to plan activities and meet goals. There are qualitative and quantitative forecasting methods. Qualitative methods include expert opinions, while quantitative methods use past data patterns in time series models. Common time series models are moving averages, which smooth fluctuations, and exponential smoothing, which weights recent data higher. Forecasts are compared to actuals to measure error using metrics like mean absolute deviation and standard error of estimate. Accurate forecasting allows businesses to better allocate resources and serve customers.
This document discusses time series analysis and its objectives, components, and techniques. It contains the following key points in 3 sentences:
Time series analysis involves decomposing a variable's values over successive time intervals into various factors like trends, cycles, seasonality, and irregular components. The objectives are to study past behavior to facilitate forecasting future values. The document describes techniques for time series analysis including simple and weighted moving averages as well as exponential smoothing.
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2. Plan – Day1
• Morning:
• Brief overview of Time Series Analysis
• Seasonality and its determinants
• Decomposition models
• Exploration tools
• Why Seasonal Adjustment?
• Step by step procedures for SA
• Afternoon:
• Using JDemetra+
• Getting familiar
• First results
• Question time for face-to-face discussion with the trainers
3. Plan – Day2
• Morning:
• Identification of types of outliers:
• Calendar Effect and its determinants
• X-13 ARIMA vs. Tramo/Seats
• How to use the ESS guidelines on SA
• Afternoon:
• Using JDemetra+
• Calendar Adjustment
• Outliers
• Question time for face-to-face discussion with the trainers
4. Plan – day3
• Morning:
• Using JDemetra+
• Full exercise with ESTAT series
• Full exercise with MS series
• Afternoon:
• Using JDemetra+
• Show and tell exercise by participants
• Conclusions and evaluation of the course
5. What is a Time Series?
A Time Series is a sequence of measures of a given
phenomenon taken at regular time intervals such as hourly,
daily, weekly, monthly, quarterly, annually, or every so many
years
– Stock series are measures of activity at a point in time and can be
thought of as stocktakes (e.g. the Monthly Labour Force Survey takes
stock of whether a person was employed in the reference week)
– Flow series are series which are a measure of activity to a date (e.g.
Retail, Current Account Deficit, Balance of Payments)
7. 2008 2009
Q1 Q2 M8 Q4 Q1 Q2 Q3 Q4
100 200 30 250 90 120 100 190
Look at the kind of data!!!
What is a Time Series?
Is this a Time Series?
8. What is a Time Series?
Is this a Time Series?
2008 2009
Q1 Q2 Q4 Q1 Q2 Q3 Q4
100 200 250 90 120 100 190
9. Usual Components
• The Trend Component
• The Trend is the long term evolution of the series that
can be observed on several decades
• The Cycle Component
• The Cycle is the smooth and quasi-periodic movement of
the series that can usually be observed around the long
term trend
• The Seasonal Component (Seasonality)
• Fluctuations observed during the year (each month,
each quarter) and which appear to repeat themselves on
a more or less regular basis from one year to other
10. Usual Components
• The Calendar Effect
• Any economic effect which appears to be related to the
calendar (e.g. one more Sunday in the month can affect
the production)
• The Irregular Component
• The Irregular Component is composed of residual and
random fluctuations that cannot be attributed to the
other “systematic” components
• Outliers
• Different kinds of Outliers can be defined
• year to other
16. Trend
• The Trend Component is defined as the long-
term movement in a series
• The Trend is a reflection of the underlying level of
the series. This is typically due to influences such
as population growth, price inflation and general
economic development
• The Trend Component is sometimes referred to
as the Trend-Cycle (see Cycle Component)
17. Cause of Seasonality
• Seasonality and Climate: due to the variations of the
weather and of the climate (seasons!)
• Examples: agriculture, consumption of electricity (heating)
• Seasonality and Institutions: due to the social habits
and practices or to the administrative rules
• Examples: effect of Christmas on the retail trade, of the fiscal
year on some financial variables, of the academic calendar
• Indirect Seasonality: due to the Seasonality that affects
other sectors
• Examples: toy industry is affected a long time before
Christmas. A Seasonal increase in the retail trade has an
impact on manufacturing, deliveries, etc..
18. Seasonal Adjustment
• Seasonal Adjustment is the process of estimating and
removing the Seasonal Effects from a Time Series, and
by Seasonal we mean an effect that happens at the same
time and with the same magnitude and direction every year
• The basic goal of Seasonal Adjustment is to decompose a
Time Series into several different components, including a
Seasonal Component and an Irregular Component
• Because the Seasonal effects are an unwanted feature of
the Time Series, Seasonal Adjustment can be thought of as
focused noise reduction
19. Seasonal Adjustment
• Since Seasonal effects are annual effects, the
data must be collected at a frequency less
than annually, usually monthly or quarterly
• For the data to be useful for Time Series analysis,
the data should be comparable over time. This
means:
• The measurements should be taken over discrete
(nonoverlapping) consecutive periods, i.e., every month
or every quarter
• The definition of the concept and the way it is measured
should be consistent over time
20. Seasonal Adjustment
• Keep in mind that longer series are NOT
necessarily better. If the series has changed the
way the data is measured or defined, it might be
better to cut off the early part of the series to keep
the series as homogeneous as possible
• The best way to decide if your series needs to be
shortened is to investigate the data collection
methods and the economic factors associated with
your series and choose a length that gives you the
most homogeneous series possible
21. Seasonal Adjustment
• During Seasonal Adjustment, we remove Seasonal
Effects from the original series. If present, we also
remove Calendar Effects. The Seasonally Adjusted
series is therefore a combination of the Trend and
Irregular Components
• One common misconception is that Seasonal
Adjustment will also hide any Outliers present. This
is not the case. If there is some kind of unusual
event, we need that information for analysis, and
Outliers are included in the Seasonally Adjusted series
22. Q1 Q2 Q3 Q4
2008 100 200 130 250
2009 90 120 100 190
2010 150 250 240 300
2011 90 120 100 190
I-II II-III III-IV IV-I
2008 +100 -70 +120 -160
2009 +30 -20 +90 -40
2010 +100 -10 +60 -210
2011 +30 -20 +90
What happens if we change a value?
Time Series Differences
Seasonal Adjustment
A first overview
24. I-II II-III III-IV IV-I
2008 + - + -
2009 + - + -
2010 + - + -
2011 + + +
It may be an outlier:
Additive Outlier
Level Shift
Transitory Change
Differences
Seasonal Adjustment
A first overview
25. I-II II-III III-IV IV-I
2008 + - + -
2009 + - + -
2010 + - + -
2011 + - +
This table is good for the first order
stationary (mean), but it is not able
to find a non-stationary of second
order (variance)
Differences
Seasonal Adjustment
A first overview
30. Calendar Adjustment
• Calendar Effects typically include:
• Different number of Working Days in a specific period
• Composition of Working Days
• Leap Year effect
• Moving Holidays (Easter, Ramadan, etc.)
31. Calendar Adjustment - Trading Day Effect
• Recurring effects associated with individual days of the week.
This occurs because only non-leap-year Februaries have four
of each type of day: four Mondays, four Tuesdays, etc.
• All other months have an excess of some types of days. If
an activity is higher on some days compared to others, then
the series can have a Trading Day effect. For example,
building permit offices are usually closed on Saturday and
Sunday
• Thus, the number of building permits issued in a given month
is likely to be higher if the month contains a surplus of
weekdays and lower if the month contains a surplus of
weekend days
32. Calendar Adjustment - Moving Holiday Effect
• Effects from holidays that are not always on
the same day of a month, such as Labor Day
or Thanksgiving. The most important Moving
Holiday in the US and European countries is
Easter, not only because it moves between days,
but also because it moves between months since
it can occur in March or April
33. Irregular Component
• The Irregular Component is the remaining component of the series
after the Seasonal and Trend Components have been removed
from the original data
• For this reason, it is also sometimes referred to as the Residual
Component. It attempts to capture the remaining short term
fluctuations in the series which are neither systematic nor predictable
34. Exploration – Basic tools
• Exploration is a very essential step when
analyzing a Time Series
• Looking for “structures” in the series
• Trend, Seasonality, “strange” points or behavior etc.
• Helps to formulate a global or decomposition
model for the series
• Graphics are a key player in this exploration
38. Why Seasonal Adjustment?
• Business cycle analysis
• To improve comparability:
• Over time:
o Example: how to compare the first quarter (with February)
to the fourth quarter (with Christmas)?
• Across space:
o Never forget that while we are freezing at work,
Australians are burning on the beach!
o Very important to compare European national economies
(convergence of business cycles) or sectors
43. Why Seasonal Adjustment?
• The aim of Seasonal Adjustment is to eliminate
Seasonal and Calendar Effects. Hence there are no
Seasonal and Calendar Effects in a perfectly
Seasonally Adjusted series
• In other words: Seasonal Adjustment transforms the
world we live in into a world where no Seasonal and
Calendar Effects occur. In a Seasonally Adjusted world
the temperature is exactly the same in winter as in
the summer, there are no holidays, Christmas is
abolished, people work every day in the week with the
same intensity (no break over the weekend), etc.
44. Step by step procedures for SA
• Step 0: Number of observations
• It is a requirement for Seasonal Adjustment that the
Times Series have to be at least 3 years-long (36
observations) for monthly series and 4 years-long (16
observations) for quarterly series. If a series does not
fulfill this condition, it is not long enough for Seasonal
Adjustment. Of course these are minimum values,
series can be longer for an adequate adjustment or for
the computation of diagnostics depending on the fitted
ARIMA model
45. Step by step procedures for SA
• Step 1: Graph
• It is important to have a look at the data and graph of the
original Time Series before running a Seasonal Adjustment
method
• Series with possible Outlier values should be identified.
Verification is needed concerning that the outliers are valid
and there is not sign problem in the data for example
captured erroneously
• The missing observations in the Time Series should be
identified and explained. Series with too many missing values
will cause estimation problems
• If series are part of an aggregate series, it should be verified
that the starting and ending dates for all component series
are the same
• Look at the Spectral Graph of the Original Series (optional)
46. Step by step procedures for SA
• Step 2: Constant in variance
• The type of transformation should be used automatically.
Confirm the results of the automatic choice by looking at graphs
of the series. If the diagnostics for choosing between Additive
and Multiplicative decomposition models are inconclusive, then
you can chose to continue with the type of transformation used in
the past to allow for consistency between years or it is
recommended to visually inspect the graph of the series
• If the series has zero and negative values, then this series must
be additively adjusted
• If the series has a decreasing level with positive values close to
zero, then multiplicative adjustment must be used
47. Step by step procedures for SA
• Step 3: Calendar Effects
• It should be determined which regression effects, such as
Trading/Working Day, Leap Year, Moving Holidays (e.g.
Easter) and national holidays, are plausible for the series
• If the effects are not plausible for the series or the coefficients for
the effect are not significant, then regressors should not be fit for
the effects
• If the coefficients for the effects are marginally significant, then it
should be determined if there is a reason to keep the effects in the
model
• If the automatic test does not indicate the need for Trading Day
regressor, but there is a peak at the first trading day frequency of
the spectrum of the residuals, then it may fit a Trading Day
regressor manually
• If the series is long enough and the coefficients for the effect are
high significant then the six regressors versions of the Trading Day
effect should be used instead of one
48. Step by step procedures for SA
• Step 4: Outliers
• There are two possibilities to identify Outliers. The first is when we
identify series with possible Outlier values as in STEP 1. If some
Outliers are marginally significant, it should be analysed if there is a reason
to keep the Outliers in the model. The second possibility is when
automatic Outlier correction is used. The results should be confirmed by
looking at graphs of the series and any available information (economic,
social, etc.) about the possible cause of the detected Outlier should be used
• A high number of Outliers signifies that there is a problem related to weak
stability of the process, or that there is a problem with the reliability of the
data. Series with high number of Outliers relative to the series’ length should
be identified. This can result in regression model over-specification. The
series should be attempted to re-model with reducing the number of Outliers
• Those Outlier regressors that might be revised should be considered
carefully. Expert information about Outliers is especially important at the end
of the series because the types of these Outliers are uncertain from a
mathematical point of view and the change of type leads later to large
revisions
• Check from period to period the location of Outliers, because it should
be not always the same
49. Step by step procedures for SA
• Step 5: ARIMA model
• Automatic model identification should be used once a
year, but the re-estimation the parameters are recommended
when new observation appends. If the results are not
plausible the following procedure is advisable. High-order
ARIMA model coefficients that are not significant should be
identified. It can be helpful to simplify the model by reducing
the order of the model, taking care not to skip lags of AR
models. For Moving Average (MA) models, it is not necessary
to skip model lags whose coefficients are not significant.
Before choosing an MA model with skipped lag, the full-order
MA model should be fitted and skip a lag only if that lag’s
model coefficient is not significantly different from zero
• The BIC and AIC statistics should be looked at in order to
confirm the global quality of fit statistics
50. Step by step procedures for SA
• Step 6: Check the filter (optional)
• The critical X-11 options in X-12 ARIMA are the options that
control the extreme value procedure in the X-11 module and the
Trend Filters and Seasonal Filters used for Seasonal Adjustment
• Verify that the Seasonal Filters are in agreement generally with
the global moving Seasonality ratio
• After reviewing the Seasonal Filter choices, the Seasonal Filters in
the input file should be set to the specific chosen length so they
will not change during the production
• The SI-ratio Graphs in the X-12 ARIMA output file should be
looked at. Any month with many extreme values relative to the
length of the time series should be identified. This may be
needed for raising the sigma limits for the extreme value
procedure
51. Step by step procedures for SA
• Step 7: Residuals
• There should not be any residual Seasonal and Calendar
Effects in the published Seasonally Adjusted series or in
the Irregular Component
• The spectral graph of the Seasonally Adjusted series and the
Irregular Component should be looked at (optional). If there is
residual Seasonality or Calendar Effect, as indicated by the
spectral peaks, the model and regressor options should be
checked in order to remove residual peaks
• If the series is a composite indirect adjustment of several
component series, the checks mentioned above in aggregation
approach should be performed
• Among others the diagnostics of normality and Ljung-Box Q-
statistics should be looked at in order to check the residuals of
the model
52. Step by step procedures for SA
• Step 8: Diagnostic
• The stability diagnostics for Seasonal Adjustment are
the sliding spans and revision history. Large revisions
and instability indicated by the history and sliding spans
diagnostics show that the Seasonal Adjustment is not
useful
53. Step by step procedures for SA
• Step 9: Publication policy
• A reference paper with the quality report (if it is available)
should be issued once a year as a separate publication which
has to include the following information:
1. The Seasonal Adjustment method in use
2. The decision rules for the choice of different options in the
program
3. The aggregation policy
4. The Outlier detection and correction methods
5. The decision rules for transformation
6. The revision policy
7. The description of the Working/Trading Day adjustment
8. The contact address
54. day2, morning
• Identification of types of Outliers
• Additive outlier
• Transitory change
• Level shift
• Calendar Effect and its determinants
• Trading days
• Moving holidays
• X-13 ARIMA vs. Tramo/Seats
• How to use the ESS guidelines on SA
55. Outliers
• Outliers are data which do not fit in the tendency of the Time Series
observed, which fall outside the range expected on the basis of the
typical pattern of the Trend and Seasonal Components
• Additive Outlier (AO): the value of only one observation is affected.
AO may either be caused by random effects or due to an identifiable
cause as a strike, bad weather or war
• Temporary Change (TC): the value of one observation is extremely
high or low, then the size of the deviation reduces gradually
(exponentially) in the course of the subsequent observations until the
Time Series returns to the initial level
• Level Shift (LS): starting from a given time period, the level of the
Time Series undergoes a permanent change. Causes could include:
change in concepts and definitions of the survey population, in the
collection method, in the economic behavior, in the legislation or in
the social traditions
60. Additive Outliers:
Unusual high or low singular
values in the data series
Transitory Changes:
Transitory changes in the
trend, followed by slow
comebacks to the initial
tendency
Level Shift:
Clear changes of the trend
Assimilated to
the Irregular
Component
Assimilated to
the Trend
Component
Outliers
61. Outliers
• The smoothness of series can be decided by
statisticians and the policy must be defined in advance
• Consult the users
• This choice can influence dramatically the credibility
• Outliers in last quarter are very difficult to be identified
• Some suggestions:
• Look at the growth rates
• Conduct a continuous analysis of external sources to
identify reasons of Outliers
• Where possible always add an economic explanation
• Be transparent (LS, AO,TC)
62. Calendar Effects
• Time Series: usually a daily activity measured on a
monthly or quarterly basis only
• Flow: monthly or quarterly sum of the observed variable
• Stock: the variable is observed at a precise date
(example: first or last day of the month)
• Some movements in the series are due to the variation
in the calendar from a period to another
• Can especially be observed in flow series
• Example: the production for a month often depends on
the number of days
63. Calendar Effects
• Trading Day Effect
• Can be observed in production activities or retail sale
• Trading Days (Working Days) = days usually worked
according to the business uses
• Often these days are non-public holiday weekdays
(Monday, Tuesday, Wednesday, Thursday, Friday)
• Production usually increases with the number of working
days in the month
64. Calendar Effects
• “Day of the week” effect
• Example: Retail sale turnover is likely to be more
important on Saturdays than on other weekdays
• Statutory (Public) Holidays and Moving Holidays
• Most of statutory holidays are linked to a date, not to a
day of the week (Christmas)
• Some holidays can move across the year (Easter,
Ramadan) and their effect is not completely seasonal
• Months and quarters are not equivalent and
not directly comparable
65. X-13 ARIMA VS TRAMO/SEATS
• Seasonal Adjustment is usually done with an off-the-shelf
program. Three popular tools are:
• X-13 ARIMA (Census Bureau)
• TRAMO/SEATS (Bank of Spain)
• JDEMETRA+ (Eurostat), interface X-13 ARIMA and Tramo/Seats
• X-13 ARIMA is Filter based: always estimate a Seasonal
Component and remove it from the series even if no
Seasonality is present, but not all the estimates of the
Seasonally Adjusted series will be good
• TRAMO/SEATS is model based: method variants of
decomposition of Time Series into non-observed components
66. X-13 ARIMA
• A Filter is a weighted average where the weights sum to 1
• Seasonal Filters are the filters used to estimate the
Seasonal Component. Ideally, Seasonal Filters are
computed using values from the same month or quarter
(for example an estimate for January would come from a
weighted average of the surrounding Januaries)
• The Seasonal Filters available in X-13 ARIMA consist of
seasonal Moving Averages of consecutive values within a
given month or quarter. An n x m Moving Average is an
m-term simple average taken over n consecutive
sequential spans
67. X-13 ARIMA
• An example of a 3x3 filter (5 terms) for January 2003 (or Quarter
1, 2003) is:
2001.1 + 2002.1 + 2003.1 +
2002.1 + 2003.1 + 2004.1 +
2003.1 + 2004.1 + 2005.1
9
• An example of a 3x5 filter for January 2003 (or Quarter 1, 2003)
is:
2000.1 + 2001.1 + 2002.1 + 2003.1 + 2004.1 +
2001.1 + 2002.1 + 2003.1 + 2004.1 + 2005.1 +
2002.1 + 2003.1 + 2004.1 + 2005.1 + 2006.1
15
68. X-13 ARIMA
• Trend Filters are weighted averages of consecutive
months or quarters used to estimate the trend component
• An example of a 2x4 filter (5 terms) for First Quarter
2005:
2004.3 + 2004.4 + 2005.1 + 2005.2
2004.4 + 2005.1 + 2005.2 + 2005.3
8
• Notice that we are using the closest points, not just the
closest points within the First Quarter like with the
Seasonal Filters above
• Notice also that every quarter has a weight of 1/4, though
the Third Quarter uses values in both 2004 and 2005
69. TRAMO/SEATS
• The objective of the procedure is to automatically identify
the model fitting the Time Series and estimate the model
parameters. This includes:
• The selection between additive and multiplicative model types
(log-test)
• Automatic detection and correction of Outliers, eventual
interpolation of missing values
• Testing and quantification of the Trading Day effect
• Regression with user-defined variables
• Identification of the ARIMA model fitting the Time Series, that is
selection of the order of differentiation (unit root test) and the
number of autoregressive and Moving Average parameters, and
also the estimation of these parameters
70. TRAMO/SEATS
• The application belongs to the ARIMA model-based method
variants of decomposition of Time Series into non-observed
components
• The decomposition procedure of the SEATS method is built on
spectrum decomposition
• Components estimated using Wiener-Kolmogorov Filter
• SEATS assumes that:
• The Time Series to be Adjusted Seasonally is linear, with normal
White Noise innovations
• If this assumption is not satisfied, SEATS has the capability to
interwork with TRAMO to eliminate special effects from the series,
identify and eliminate Outliers of various types, and interpolate
missing observations
• Then the ARIMA model is also borrowed from TRAMO
71. TRAMO/SEATS
• The application decomposes the series into several
various components. The decomposition may be either
multiplicative or additive
• The components are characterized by the spectrum or the
pseudo spectrum in a non-stationary case:
• The Trend Component represents the long-term development of
the Time Series, and appears as a spectral peak at zero
frequency. One could say that the Trend is a Cycle with an
infinitely long period
• The effect of the Seasonal Component is represented by spectral
peaks at the seasonal frequencies
• The Irregular Component represents the irregular White Noise
behaviour, thus its spectrum is flat (constant)
• The Cyclic Component represents the various deviations from the
trend of the Seasonally Adjusted series, different from the pure
White Noise
72. TRAMO/SEATS
• First SEATS decomposes the ARIMA model of the Time Series
observed, that is, identifies the ARIMA models of the components.
This operation takes place in the frequency domain. The spectrum is
divided into the sum of the spectra related to the various components
• Actually SEATS decides on the basis of the argument of roots, which
is mostly located near to the frequency of the spectral peak
• The roots of high absolute value related to 0 frequency are assigned
to the Trend Component
• The roots related to the seasonal frequencies to the Seasonal
Component
• The roots of low absolute value related to 0 frequency and the Cyclic
(between 0 and the first Seasonal frequency) and those related to
frequencies between the Seasonal ones are assigned to the Cyclic
Component
• The Irregular Component is always deemed as white noise
73. ESS Guidelines on SA
• Introduced in 2009 and revised in 2015
• Chapters subdivided into specific items describing different
steps of the SA process
• Items presented in a standard structure providing:
1. Description of the issue
2. List of options which could be followed to perform the step
3. Prioritized list of three alternatives from most recommended one
to the one to avoid (A, B and C)
4. Concise list of main references
• Added value:
1. Conceptual framework and practical implementation steps
2. Both for experienced users and beginners
74. Historical background
• Since early nineties:
• Informal group on Seasonal Adjustment
• Stocktaking exercise:
• BV4, Dainties, SABL, Census family (X-11, X-12 ARIMA etc.),
TRAMO/SEATS
• Criteria (among others):
• Estimation of a Calendar Component
• Treatment of Outliers
• Statistical tests
• Long and controversial discussions:
• At the end preference for X-12-ARIMA and TRAMO/SEATS
75. Historical background
• EUROSTAT developed DEMETRA+ in order to support
comparisons between X-12-ARIMA and TRAMO/SEATS
• ECB/EUROSTAT Seasonal Adjustment Steering Group was
founded to promote further harmonization
• After the EUROSTAT crises, the work on the Guidelines started
• 2008: Agreement on the guidelines of the CMFB and the SPC
• 2012: The National Bank of Belgium in collaboration with
EUROSTAT developed JDEMETRA+, an open source tool for
SA
• 2012-2013: Task Force for the revision of the ESS Guidelines
on SA, final version published in May 2015
76. JDEMETRA+
• JDEMETRA+ is not only a user-friendly graphical interface,
comparable with DEMETRA+, but also a set of open Java libraries
that can be used to deal with time series related issues
• JDEMETRA+ is built around the concepts and the algorithms used
in the two leading SA methods, i.e. TRAMO/SEATS and X-12
ARIMA / X-13 ARIMA SEATS
• The algorithms have been reengineered, following an object-
oriented approach, that allows for easier handling, extensions or
modifications
• X-13 ARIMA SEATS includes a module that uses the ARIMA model
based seasonal adjustment procedure from the SEATS seasonal
adjustment program