Building Real-Time Data Pipelines: A Practical Guide - Data Engineering Process Fundamentals

Overview

In modern data engineering solutions, handling streaming data is very important. Businesses often need real-time insights to promptly monitor and respond to operational changes and performance trends. A data streaming pipeline facilitates the integration of real-time data into data warehouses and visualization dashboards.

• Follow this GitHub repo during the presentation: (Give it a star)

👉 https://github.com/ozkary/data-engineering-mta-turnstile

• Read more information on my blog at:

👉 https://www.ozkary.com/2023/03/data-engineering-process-fundamentals.html

YouTube Video

Video Agenda

1. What is Data Streaming?

   • Understanding the concept of continuous data flow.

   • Real-time vs. batch processing.

   • Benefits and use cases of data streaming.

2. Data Streaming Channels

   • APIs (Application Programming Interfaces)

   • Events (system-generated signals)

   • Webhooks (HTTP callbacks triggered by events)

3. Data Streaming Components

   • Message Broker (Apache Kafka)

   • Producers and consumers

   • Topics for data categorization

   • Stream Processing Engine (Apache Spark Structured Streaming)

4. Solution Design and Architecture

   • Real-time data source integration

   • Leveraging Kafka for reliable message delivery

   • Spark Structured Streaming for real-time processing

   • Writing processed data to the data lake

5. Q&A Session

   • Get your questions answered by the presenters.

Why Join This Session?

• Stay Ahead of the Curve: Gain a comprehensive understanding of data streaming, a crucial aspect of modern data engineering.
• Unlock Real-Time Insights: Learn how to leverage data streaming for immediate processing and analysis, enabling faster decision-making.
• Learn Kafka and Spark: Explore the power of Apache Kafka as a message broker and Apache Spark Structured Streaming for real-time data processing.
• Build a Robust Data Lake: Discover how to integrate real-time data into your data lake for a unified data repository.

Presentation

Introduction - What is Data Streaming?

Data streaming enables us to build data integration in real-time. Unlike traditional batch processing, where data is collected and processed periodically, streaming data arrives continuously, and it is processed on-the-fly.

• Understanding the concept of continuous data flow
  • Real-time, uninterrupted transfer of data from various channels.
  • Allows for immediate processing and analysis of data as it is generated.
• Real-time vs. batch processing
  • Data is collected and process in chunks at certain times
  • The data can take hours and even days depending on the source
• Benefits and use cases of data streaming
  • React instantly to events
  • Predict trends with real-time updates
  • Update dashboard with up to the minute/seconds data

Data Streaming Channels

Data streams can arrive from various channels, often hosted on HTTP endpoints. The specific channel technology depends on the provider. Generally, the integration involves either a push or a pull connection.

• Events (Push Model): These can be delivered using a subscription model like Pub/Sub, where your system subscribes to relevant topics and receives data "pushed" to it whenever events occur. Examples include user clicks, sensor readings, or train arrivals.

• Webhooks (Push-Based on Events): These are HTTP callbacks triggered by specific events on external platforms. You set up endpoints that listen for these notifications to capture the data stream.

• APIs (Pull Model): Application Programming Interfaces are used to actively fetch data from external services, like social media platforms. Scheduled calls are made to the API at specific intervals to retrieve the data.

Data Streaming System

Powering real-time data pipelines, Apache Kafka efficiently ingests data streams, while Apache Spark analyzes and transforms it, enabling large-scale insights.

Apache Kafka:

Apache Kafka: The heart of the data stream. It's a high-performance platform that acts as a message broker, reliably ingesting data (events) from various sources like applications, sensors, and webhooks. These events are published to categorized channels (topics) within Kafka for further processing.

Spark Structured Streaming:

Built on Spark, it processes Kafka data streams in real-time. Unlike simple ingestion, it allows for transformations, filtering, and aggregations on the fly, enabling real-time analysis of streaming data.

Data Streaming Components

Apache Kafka acts as the central message broker, facilitating real-time data flow. Producers, like applications or sensors, publish data (events) to categorized channels (topics) within Kafka. Spark then subscribes as a consumer, continuously ingesting and processing these data streams in real-time.

• Message Broker (Kafka): Routes real-time data streams.
• Producers & Consumers: Producers send data to topics, Consumers receive and process it.
• Topics (Categories): Organize data streams by category.
• Stream Processing Engine (Spark Structured Streaming):
  • Reads data from Kafka.
  • Extracts information.
  • Transforms & summarizes data (aggregations).
  • Writes to a data lake.

Use case Background

The Metropolitan Transportation Authority (MTA) subway system in New York has stations around the city. All the stations are equipped with turnstiles or gates which tracks as each person enters (departure) or exits (arrival) the station.

• The MTA subway system has stations around the city.
• All the stations are equipped with turnstiles or gates which tracks as each person enters or leaves the station.
• CSV files provide information about the amount of commuters per stations at different time slots.

Data Specifications

Since we already have a data transformation layer that incrementally updates the data warehouse, our real-time integration will focus on leveraging this existing pipeline. We'll achieve this by aggregating data from the stream and writing the results directly to the data lake.

• Group by these categorical fields: "AC", "UNIT","SCP","STATION","LINENAME","DIVISION", "DATE", "DESC"
• Aggregate these measures: "ENTRIES", "EXITS"
• Sample result: "A001,R001,02-00-00,Test-Station,456NQR,BMT,09-23-23,REGULAR,16:54:00,140,153"

# Define the schema for the incoming data
turnstiles_schema = StructType([
    StructField("AC", StringType()),
    StructField("UNIT", StringType()),
    StructField("SCP", StringType()),
    StructField("STATION", StringType()),
    StructField("LINENAME", StringType()),
    StructField("DIVISION", StringType()),
    StructField("DATE", StringType()),
    StructField("TIME", StringType()),
    StructField("DESC", StringType()),
    StructField("ENTRIES", IntegerType()),
    StructField("EXITS", IntegerType()),
    StructField("ID", StringType()),
    StructField("TIMESTAMP", StringType())
])

Solution Architecture for Real-time Data Integration

Data streams are captured by the Kafka producer and sent to Kafka topics. The Spark-based stream consumer retrieves and processes the data in real-time, aggregating it for storage in the data lake.

Components:

• Real-Time Data Source: Continuously emits data streams (events or messages).
• Message Broker Layer:
  • Kafka Broker Instance: Acts as a central hub, efficiently collecting and organizing data into topics.
  • Kafka Producer (Python): Bridges the gap between the source and Kafka.
• Stream Processing Layer:
  • Spark Instance: Processes and transforms data in real-time using Apache Spark.
  • Stream Consumer (Python): Consumes messages from Kafka and acts as both a Kafka consumer and Spark application:
    • Retrieves data as soon as it arrives.
    • Processes and aggregates data.
    • Saves results to a data lake.
• Data Storage: Data transformation for visualization tools (Looker, Power BI) to access.
• Docker Containers: Use containers for deployments

Data Transformation and Incremental Strategy

The data transformation phase is a critical stage in a data warehouse project. This phase involves several key steps, including data extraction, cleaning, loading, data type casting, use of naming conventions, and implementing incremental loads to continuously insert the new information since the last update via batch processes.

Data Lineage: Tracks the flow of data from its origin to its destination, including all the intermediate processes and transformations that it undergoes.

Impact on Data Visualization

• Our architecture efficiently processes real-time data by leveraging our existing data transformation layer.
• This optimized flow enables significantly faster data visualization.
• The dashboard refresh time can increase their frequency to load the new data.

For real-time updates directly on the dashboard, a socket-based integration would be necessary.

Key Takeaways: Real-Time Integration

Data streaming solutions are an absolute necessity, enabling the rapid processing and analysis of vast amounts of real-time data. Technologies like Kafka and Spark play a pivotal role in empowering organizations to harness real-time insights from their data streams.

• Real-time Power: Kafka handles various data streams, feeding them to data topics.
• Spark Processing Power: Spark reads from these topics, analyzes messages in real-time, and aggregates the data to our specifications.
• Existing Pipeline Integration: Leverages existing pipelines to write data to data lakes for transformation.
• Faster Insights: Delivers near real-time information for quicker data analysis and visualization.

We've covered a lot today, but this is just the beginning!

If you're interested in learning more about building cloud data pipelines, I encourage you to check out my book, 'Data Engineering Process Fundamentals,' part of the Data Engineering Process Fundamentals series. It provides in-depth explanations, code samples, and practical exercises to help in your learning.

Thanks for reading.

Send question or comment at Twitter @ozkary 👍 Originally published by ozkary.com

May the Tech Force Be With You: Unlock Your Career Journey in Technology

Overview

Curious about the possibilities and where your passion fits in the ever-evolving world of technology? Join us as we decode your unique technical journey! This presentation is designed to equip you with the knowledge and confidence to navigate your path in the exciting world of technology

YouTube Video

Video Agenda

• What's Next?:

  • Understanding the Technical Landscape.
  • Continuous Learning.
  • Exploring Industry Trends and Job Market.

• Explore Your Passion: Diverse Areas of Specialization:

  • Showcase different areas of CS specialization (e.g., web development, data science, artificial intelligence, cybersecurity).

• Building Blocks of Tech: Programming Languages:

  • Showcase and explain some popular programming languages used in different areas.

• Beyond Coding: Programming vs. Non-Programming Roles:

  • Debunk the myth that all CS careers involve coding.
  • Introduce non-programming roles in tech.

• Code-Centric vs. Low-Code/No-Code Development:

  • Explain the concept of code-centric and low-code/no-code development approaches.
  • Discuss the advantages and disadvantages of each approach.

• The Future is Bright:

  • Discuss emerging technologies like AI, cloud computing, and automation, and their impact on the future of CS careers.
  • Emphasize the importance of continuous learning and adaptability in this ever-changing landscape.

Why Attend?

• In-demand skills: Discover the technical and soft skills sought after by employers in today's tech industry.
• Matching your passion with a career: Explore diverse areas of specialization and identify the one that aligns with your interests and strengths.
• Career paths beyond coding: Uncover a range of opportunities in tech, whether you're a coding whiz or have a different area of expertise.
• Future-proofing your career: Gain knowledge of emerging technologies and how they'll shape the future of computer science.

By attending, you'll leave equipped with the knowledge and confidence to make informed decisions about your future in the ever-evolving world of technology.

Presentation

What's Next for Your Tech Career?

Feeling overwhelmed by the possibilities after graduation? You're not alone! Learning never ends, as there are some Technical foundation (hard skills) areas to consider as you embark on a tech career.

• Understanding the Technical Landscape
  • Stay Informed: Keep up with the latest trends and advancements in technology
  • Broaden Your Horizons: Look beyond your core area of study. Explore other fields
• Continuous Learning and Skill Development
  • Adapt and Evolve: The tech industry is constantly changing
  • Technical Skills: Focus on in-demand skills such as Cloud Computing, Cybersecurity, and Data Science

Technical skills are crucial, but success in the tech industry also hinges on strong soft skills. These skills are essential for success in today's collaborative tech environment:

Networking and Professional Growth:

• Build Your Tech Network: Connect and collaborate with online and offline tech communities.
• Invest in Your Soft Skills: Enhance your communication, teamwork, and problem-solving skills.
• Find Your Tech Mentor: Seek guidance and support from experienced professionals.

The tech industry is bursting with opportunities. To navigate this exciting landscape and land your dream job, consider these key areas to craft your career roadmap and take a chance:

• Work style Preferences:

  • Remote vs. Relocation: Do you thrive in a remote work environment, or are you open to relocating for exciting opportunities?
  • Big Companies vs. Startups: Compare the established structure and resources of large companies or the fast-paced, dynamic culture of startups.

• Explore an Industry Specialization:

  • Healthcare: Revolutionize patient care by contributing to advancements in medical technology and data analysis.
  • Manufacturing: Fuel innovation by optimizing production processes and integrating automation through industrial tech.

Diverse Areas of Specialization

Do you like creating websites? Web development might be your calling. Do you dream of building mobile apps? Mobile development could be your fit. Are you intrigued by the power of data and its ability to unlock valuable insights? Data science might be your ideal path.

• Web Development: Build user interfaces and functionalities for websites and web applications.
• Mobile Development: Create applications specifically designed for smartphones and tablets.
• Data Engineering: Build complex data pipelines and data storage solutions.
• Data Analyst: Process data, discover insights, create visualizations
• Data Science: Analyze large datasets to extract valuable insights and inform decision-making.
• Artificial Intelligence: Develop intelligent systems that can learn and make decisions.
• Cloud Engineering: Design, build, and manage applications and data in the cloud.
• Cybersecurity: Protect computer systems and networks from digital threats
• Game Development: Create video games and AR experiences

Building Blocks of Tech: Programming Languages

The world of software development hinges on a powerful tool - programming languages. These languages, with their unique syntax and functionalities, has advantages for certain platforms like Web, Data, Mobile.

• Versatile Languages:

  • JavaScript (JS): The king of web development, also used for building interactive interfaces and mobile apps (React Native).
  • Python: A beginner-friendly language, popular for data science, machine learning, web development (Django), and automation.
  • Java: An industry standard, widely used for enterprise applications, web development (Spring), and mobile development (Android), high-level programming.
  • C#: A powerful language favored for game development (Unity), web development (ASP.NET), and enterprise applications.
  • SQL: A powerful language essential for interacting with relational databases, widely used in web development, data analysis, and business intelligence.

• Specialized Languages:

  • PHP: Primarily used for server-side scripting and web development (WordPress).
  • C++: A high-performance language for system programming, game development, and scientific computing, low-level programming.

• Mobile-Centric Languages:

  • Swift: The go-to language for native iOS app development.
  • Objective-C: The predecessor to Swift, still used in some legacy iOS apps.

• JavaScript Extensions:

  • TypeScript: A superset of JavaScript, adding optional static typing for larger web applications.

Beyond Coding: Programming vs. Non-Programming Roles

Programming involve writing code to create apps and systems. Non-programming tech roles, like project managers, QA, UX designers, and technical writers, use their skills to guide the development process, design user experiences, and document technical information.

• Programming Roles: Developers, software engineers, data engineers
• Non-Programming Roles: Project managers, systems analysts, user experience (UX) designers, QA, DevOps, technical writers.

The industry continuous to define new specialized roles.

Empowering Everyone: Code-Centric vs. Low-Code/No-Code Development

Do you enjoy diving into the code itself using tools like Visual Studio Code? Or perhaps you prefer a more visual approach, leveraging designer tools and writing code snippets when needed?

• Code-Centric Development:

  • Traditional approach where developers write code from scratch using programming languages like Python, C#, or C++.
  • Offers maximum flexibility and control over the application's functionality and performance.
  • Requires strong programming skills and a deep understanding of software development principles.

• Low-Code/No-Code Development:
  • User-friendly platforms that enable rapid application development with minimal coding or no coding required.
  • Utilize drag-and-drop interfaces, pre-built components, and templates to streamline the development process.
  • Ideal for building simple applications, automating workflows, or creating prototypes.

Evolving with Technology

The landscape of software development is constantly transforming, with new technologies like AI, low-code/no-code platforms, automation, and cloud engineering emerging. Keep evolving!

• AI as a Co-Pilot: AI won't replace programmers; it will become a powerful collaborator. Imagine AI tools that:

  • Generate code snippets based on your requirements.
  • Refactor and debug code for efficiency and security.
  • Automate repetitive tasks, freeing you for more creative problem-solving.

• Low-Code/No-Code Democratization: These platforms will empower citizen developers to build basic applications, streamlining workflows. Programmers will focus on complex functionalities and integrating these solutions.

• Automation Revolution: Repetitive coding tasks will be automated, allowing programmers to focus on higher-level logic, system design, and innovation.

• Cloud Engineering Boom: The rise of cloud platforms will create a demand for skilled cloud engineers who can design, build, and manage scalable applications in the cloud.

Final Thoughts: Your Future in Tech Awaits

The tech world is yours to explore! Keep learning, join a community, choose your path in tech and industry, and build your roadmap. Find a balance between your professional pursuits and personal well-being.

Thanks for reading.

Send question or comment at Twitter @ozkary 👍 Originally published by ozkary.com

Unlocking Insights: Data Analysis and Visualization - Data Engineering Process Fundamentals

Overview

Delve into unlocking the insights from our data with data analysis and visualization. In this continuation of our data engineering process series, we focus on visualizing insights. We learn about best practices for data analysis and visualization, we then move into an implementation using a code-centric dashboard using Python, Pandas and Plotly. We then follow up by using a high-quality enterprise tool, such as Looker, to construct a low-code cloud-hosted dashboard, providing us with insights into the type of effort each method takes.

• Follow this GitHub repo during the presentation: (Give it a star)

👉 https://github.com/ozkary/data-engineering-mta-turnstile

• Read more information on my blog at:

👉 https://www.ozkary.com/2023/03/data-engineering-process-fundamentals.html

YouTube Video

Video Agenda

1. Introduction:

   Recap the importance of data warehousing, data modeling and transition to data analysis and visualization.

2. Data Analysis Foundations:

   Data Profiling: Understand the structure and characteristics of your data. Data Preprocessing: Clean and prepare data for analysis. Statistical Analysis: Utilize statistical techniques to extract meaningful patterns. Business Intelligence: Define key metrics and answer business questions. Identifying Data Analysis Requirements: Explore filtering criteria, KPIs, data distribution, and time partitioning.

3. Mastering Data Visualization:

   Common Chart Types: Explore a variety of charts and graphs for effective data visualization. Designing Powerful Reports and Dashboards: Understand user-centered design principles for clarity, simplicity, consistency, filtering options, and mobile responsiveness. Layout Configuration and UI Components: Learn about dashboard design techniques for impactful presentations.

4. Implementation Showcase:

   Code-Centric Dashboard: Build a data dashboard using Python, Pandas, and Plotly (demonstrates code-centric approach). Low-Code Cloud-Hosted Dashboard: Explore a high-quality enterprise tool like Looker to construct a dashboard (demonstrates low-code efficiency). Effort Comparison: Analyze the time and effort required for each development approach.

5. Conclusion:

Recap key takeaways and the importance of data analysis and visualization for data-driven decision-making.

Why Join This Session?

• Learn best practices for data analysis and visualization to unlock hidden insights in your data.
• Gain hands-on experience through code-centric and low-code dashboard implementations using popular tools.
• Understand the effort involved in different dashboard development approaches.
• Discover how to create user-centered, impactful visualizations for data-driven decision-making.
• This session empowers data engineers and analysts with the skills and tools to transform data into actionable insights that drive business value.

Presentation

How Do We Gather Insights From Data?

We leverage the principles of data analysis and visualization. Data analysis reveals patterns and trends, while visualization translates these insights into clear charts and graphs. It's the approach to turning raw data into actionable insights for smarter decision-making.

Let’s Explore More About:

• Data Modeling
• Data Analysis
  • Python and Jupyter Notebook
  • Statistical Analysis vs Business Intelligence
• Data Visualization
  • Chart Types and Design Principles
  • Code-centric with Python Graphs
  • Low-code with tools like Looker, PowerBI, Tableau

Data Modeling

Data modeling lays the foundation for a data warehouse. It starts with modeling raw data into a logical model outlining the data and its relationships, with a focus based on data requirements. This model is then translated, using DDL, into the specific views, tables, columns (data types), and keys that make up the physical model of the data warehouse, with a focus on technical requirements.

Importance of a Date Dimension

A date dimension allows us to analyze your data across different time granularities (e.g., year, quarter, month, day). By storing dates and related attributes in a separate table, you can efficiently join it with your fact tables containing metrics. When filtering or selecting dates for analysis, it's generally better to choose options from the dimension table rather than directly filtering the date column in the fact table.

CREATE TABLE dim_date (
  date_id INT NOT NULL PRIMARY KEY,  -- Surrogate key for the date dimension
  full_date DATE NOT NULL,          -- Full date in YYYY-MM-DD format
  year INT NOT NULL,                -- Year (e.g., 2024)
  quarter INT NOT NULL,             -- Quarter of the year (1-4)
  month INT NOT NULL,               -- Month of the year (1-12)
  month_name VARCHAR(20) NOT NULL,    -- Name of the month (e.g., January)
  day INT NOT NULL,                 -- Day of the month (1-31)
  day_of_week INT NOT NULL,            -- Day of the week (1-7, where 1=Sunday)
  day_of_week_name VARCHAR(20) NOT NULL, -- Name of the day of the week (e.g., Sunday)
  is_weekend BOOLEAN NOT NULL,        -- Flag indicating weekend (TRUE) or weekday (FALSE)
  is_holiday BOOLEAN NOT NULL,        -- Flag indicating holiday (TRUE) or not (FALSE)
  fiscal_year INT,                   -- Fiscal year (optional)
  fiscal_quarter INT                 -- Fiscal quarter (optional)  -- Optional
);

Data Analysis

Data analysis is the practice of exploring data and understanding its meaning. It involves activities that can help us achieve a specific goal, such as identifying data dimensions and measures, as well as the process to identify outliers, trends, and distributions.

• We can accomplish these activities by writing code using Python and Pandas, SQL, Jupyter Notebooks.
• We can use libraries, such as Plotly, to generate some visuals to further analyze data and create prototypes.
• The use of low-code tools also aids in the Exploratory Data Analysis (EDA) process

Data Analysis - Profiling

Data profiling is the process to identify the data types, dimensions, measures, and quantitative values, which allows the analyst to view the characteristics of the data, so we can understand how to group the information.

• Data Types: This is the type classification of the data fields. It enables us to identify categorical (text), numeric and date-time values, which define the schema
• Dimensions: Dimensions are textual, and categorical attributes that describe business entities. They are often discrete and used for grouping, filtering, organizing and partition the data
• Measures: Measures are the quantitative values that are subject to calculations such as sum, average, minimum, maximum, etc. They represent the KPIs that the organization wants to track and analyze

	dimension	data_type	measure	datetime_dimension
station_name	True	object	False	False
created_dt	True	object	False	True
entries	False	int64	True	False
exits	False	int64	True	False

Data Analysis - Cleaning and Preprocessing

Data cleaning is the process of finding bad data and outliers that can affect the results. In preprocessing, we set the data types, combine or split columns, and rename columns to follow our standards.

Bad Data:

• Bad data could be null values
• Values that are not within the range of the average trend for that day

Pre-Process:

• Cast fields with the correct type
• Rename columns and following naming conventions
• Transform values from labels to numbers when applicable

# Check for null values in each column
null_counts = df.isnull().sum()
null_counts.head()

# fill null values with a specific value
df = df.fillna(0)

# cast a column to a specific data type
df['created_dt'] = pd.to_datetime(df['created_dt'])

# get the numeric col names and cast them to int
numeric_cols = df.select_dtypes(include=[np.number]).columns
df[numeric_cols] = df[numeric_cols].astype(int)

# Rename all columns to lowercase
df.columns = [col.lower() for col in df.columns]

Data Analysis - Preprocess Outliers

Outliers are values that are notably different from the other data points in terms of magnitude or distribution. They can be either unusually high (positive outliers) or unusually low (negative outliers) in comparison to the majority of data points.

Process:

• Calculate the z-score for numeric values, which describes how far is the data point from a group of data
• Define a threshold
• Chose a value that determines when a z-score is considered high enough to be labeled as an outlier (2 or 3)
• Identify the outliers based on the z-score

# measure outliers for entries and exits
# Calculate z-scores within each station group
z_scores = df.groupby('station_name')[numeric_cols] \
        .transform(lambda x: (x - x.mean()) / x.std())

# Set a threshold for outliers
threshold = 3

# Identify outliers based on z-scores within each station
outliers = (z_scores.abs() > threshold)

# Print the count of outliers for each station
outliers_by_station = outliers.groupby(df['station_name']).sum()
print(outliers_by_station)

Data Analysis - Statistical Analysis

Statistical analysis focuses on applying statistical techniques in order to draw meaningful conclusions about a set of data. It involves mathematical computations, probability theory, correlation analysis, and hypothesis testing to make inferences and predictions based on the data. This is use for manufacturing, data science industries, machine learning.

• Pearson Correlation Coefficient and p-value are statistical measures used to assess the strength and significance of the linear relationship between two variables.
• P-Value: measures the statistical significance of the correlation
• Interpretation:
  • If the p-value is small (.05) there is solid linear correlation. Otherwise, there is no correlation

# Perform Pearson correlation test
def test_arrival_departure_correlation(df: pd.DataFrame, label: str) -> None:
   corr_coefficient, p_value = pearsonr(df['arrivals'], df['departures'])   
   p_value = round(p_value, 5)

   if p_value < 0.05:
      conclusion = f"The correlation {label} is statistically significant."
   else:
      conclusion = f"The correlation {label} is not statistically significant."

   print(f"Pearson Correlation {label} - Coefficient : {corr_coefficient} P-Value : {p_value}")    
   print(f"Conclusion: {conclusion}")

test_arrival_departure_correlation(df_top_stations, 'top-10 stations')

test_arrival_departure_correlation(df_correlation, 'all stations')

Business Intelligence and Reporting

Business intelligence (BI) is a strategic approach that involves the collection, analysis, and presentation of data to facilitate informed decision-making within an organization. In the context of business analytics, BI is a powerful tool for extracting meaningful insights from data and turning them into actionable strategies.

Analysts:

• Look at data distribution
• Understanding of data variations
• Focus analysis based on locations, date and time periods
• Provide insights that impact business operations
• Provide insights for business strategy and decision-making

# Calculate total passengers for arrivals and departures
total_arrivals = df['exits'].sum()/divisor_t
total_departures = df['entries'].sum()/divisor_t
print(f"Total Arrivals: {total_arrivals} Total Departures: {total_departures}")

# Create distribution analysis by station
df_by_station = analyze_distribution(df,'station_name',measures,divisor_t)

# Create distribution analysis by day of the week
df_by_date = df.groupby(["created_dt"], as_index=False)[measures].sum()
day_order = ['Sun', 'Mon', 'Tue', 'Wed', 'Thu', 'Fri', 'Sat']
df_by_date["weekday"] = pd.Categorical(df_by_date["created_dt"].dt.strftime('%a'), categories=day_order, ordered=True)
df_entries_by_date = analyze_distribution(df_by_date,'weekday',measures,divisor_t)

# Create distribution analysis time slots
for slot, (start_hour, end_hour) in time_slots.items():
    slot_data = df[(df['created_dt'].dt.hour >= start_hour) & (df['created_dt'].dt.hour <= end_hour)]
    arrivals = slot_data['exits'].sum()/divisor_t
    departures = slot_data['entries'].sum()/divisor_t
    print(f"{slot.capitalize()} - Arrivals: {arrivals:.2f}, Departures: {departures:.2f}")

What is Data Visualization?

Data visualization is a practice that takes the insights derived from data analysis and presents them in a visual format. While tables with numbers on a report provide raw information, visualizations allow us to grasp complex relationships and trends at a glance with the use of charts, controls and colors.

Visualization Solutions:

• A code-centric solution involves writing programs with a language like Python, JavaScript to manage the data analysis and create the visuals
• A low-code solution uses cloud-hosted tools like Looker, PowerBI and Tableau to accelerate the data analysis and visualization by using a design approach

Data Visualization - Design Principles

These design principles prioritize the user's experience by ensuring clarity, simplicity, and consistency.

• User-centered design: Focus on the needs and preferences of your audience when designing your visualizations.
• Clarity: Ensure your visualizations are easy to understand, even for people with no prior knowledge of the data.
• Simplicity: Avoid using too much clutter or complex charts.
• Consistency: Maintain a consistent visual style throughout your visualizations.
• Filtering options: Allow users to filter the data based on their specific interests.
• Device responsiveness: Design your visualizations to be responsive and viewable on all devices, including mobile phones and tablets.

Visual Perception

Over half of our brain is dedicated to processing visual information. This means our brains are constantly working to interpret and make sense of what we see.

Key elements influencing visual perception:

• Color: Colors evoke emotions, create hierarchy, and guide the eye.

• Size: Larger elements are perceived as more important. (Use different sized circles or bars to show emphasis)

• Position: Elements placed at the top or center tend to grab attention first.

• Shape: Different shapes can convey specific meanings or represent categories. (Use icons or charts with various shapes)

Statistical Analysis - Basic Charts

• Control Charts: Monitor process stability over time, identifying potential variations or defects.
• Histograms: Depict the frequency distribution of data points, revealing patterns and potential outliers.
• Box Plots: Summarize the distribution of data using quartiles, providing a quick overview of central tendency and variability.

Business Intelligence Charts

• Scorecards: Provide a concise overview of key performance indicators (KPIs) at a glance, enabling performance monitoring.
• Pie Charts: Illustrate proportional relationships between parts of a whole, ideal for composition comparisons.
• Doughnut Charts: Similar to pie charts but emphasize a specific category by leaving a blank center space.
• Bar Charts: Represent comparisons between categories using rectangular bars, effective for showcasing differences in magnitude.
• Line Charts: Reveal trends or patterns over time by connecting data points with a line, useful for visualizing continuous changes.
• Area charts: Can be helpful for visually emphasizing the magnitude of change over time.
• Stacked area charts: can be used to show multiple data series.

Data Visualization - Code Centric

Python, coupled with libraries like Plotly, Seaborn offers a versatile platform for data visualization that comes with its own set of advantages and limitations. Great for team sharing but, it is heavy in code and deployments tasks.

Data Visualization - Low Code

Instead of focusing on code, a low-code tool enables data professionals to focus on the data by using design tools with prebuilt components and connectors. The hosting and deployment is mostly managed by the providers. This is often the solution for broader sharing and enterprise solutions.

Final Thoughts

The synergy between data analysis and visualization is pivotal for data-driven projects. Navigating data analysis with established principles and communicating insights through visually engaging dashboards empowers us to extract value from data.

The Future is Bright

• Augmented Reality (AR) and Virtual Reality (VR): Imagine exploring a dataset within a 3D environment & having charts and graphs overlaid on the real world
• (AI) and Machine Learning (ML): AI can automate data analysis tasks like identifying patterns and trends, while ML can personalize visualizations based on user preferences or past interactions.
• Tools will focus on creating visualizations that are accessible to people with disabilities

We've covered a lot today, but this is just the beginning!

If you're interested in learning more about building cloud data pipelines, I encourage you to check out my book, 'Data Engineering Process Fundamentals,' part of the Data Engineering Process Fundamentals series. It provides in-depth explanations, code samples, and practical exercises to help in your learning.

Thanks for reading.

Send question or comment at Twitter @ozkary 👍 Originally published by ozkary.com

Streamlining Data Flow: Building Cloud-Based Data Pipelines - Data Engineering Process Fundamentals

Overview

Delve into the world of cloud-based data pipelines, the backbone of efficient data movement within your organization. As a continuation of our Data Engineering Process Fundamentals series, this session equips you with the knowledge to build robust and scalable data pipelines leveraging the power of the cloud. Throughout this presentation, we'll explore the benefits of cloud-based solutions, delve into key design considerations, and unpack the process of building and optimizing your very own data pipeline in the cloud.

• Follow this GitHub repo during the presentation: (Give it a star)

👉 https://github.com/ozkary/data-engineering-mta-turnstile

• Read more information on my blog at:

👉 https://www.ozkary.com/2023/03/data-engineering-process-fundamentals.html

YouTube Video

Video Agenda

About this event

This session guides you through the essential stages of building a cloud-based data pipeline:

Agenda:

Discovery: We'll embark on a journey of discovery, identifying data sources, understanding business needs, and defining the scope of your data pipeline.

Design and Planning: Here, we'll transform insights into a well-defined blueprint. We'll discuss architecture considerations, data flow optimization, and technology selection for your cloud pipeline.

Data Pipeline and Orchestration: Get ready to orchestrate the magic! This stage delves into building the pipeline itself, selecting the right tools, and ensuring seamless data movement between stages.

Data Modeling and Data Warehouse: Data needs a proper home! We'll explore data modeling techniques and the construction of a robust data warehouse in the cloud, optimized for efficient analysis.

Data Analysis and Visualization: Finally, we'll unlock the power of your data. Learn how to connect your cloud pipeline to tools for insightful analysis and compelling data visualizations.

Why Watch:

Process Power: Learn a structured, process-oriented approach to building and managing efficient cloud data pipelines.

Data to Insights: Discover how to unlock valuable information from your data using Python for data analysis.

The Art of Visualization: Master the art of presenting your data insights through compelling data visualizations.

Future-Proof Your Skills: Gain in-demand cloud data engineering expertise, including data analysis and visualization techniques.

This session equips you with the knowledge and practical skills to build a data pipelines, a crucial skill for data-driven organizations. You'll not only learn the "how" but also the "why" behind each step, empowering you to confidently design, implement, and analyze data pipelines that drive results.

Video Chapters:

0:00:00 Welcome to Data Engineering Process Fundamentals 0:02:19 Phase 1: Discovery 0:19:30 Phase 2: Design and Planning 0:33:30 Phase 3: Data Pipeline and Orchestration 0:49:00 Phase 4: Data Modeling and Data Warehouse 0:59:00 Phase 5: Data Analysis and Visualization 1:01:00 Final Thoughts

Presentation

Data Engineering Overview

A Data Engineering Process involves executing steps to understand the problem, scope, design, and architecture for creating a solution. This enables ongoing big data analysis using analytical and visualization tools.

Process Phases:

• Discovery
• Design and Planning
• Data Pipeline and Orchestration
• Data Modeling and Data Warehouse
• Data Analysis and Visualization

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👉 Data Engineering Process Fundamentals

Phase 1: Discovery Process

The discovery process involves identifying the problem, analyzing data sources, defining project requirements, establishing the project scope, and designing an effective architecture to address the identified challenges.

Activities include:

• Background & problem statement: Clearly document and understand the challenges the project aims to address.
• Exploratory Data Analysis (EDA): Make observations about the data, its structure, and sources.
• Define Project Requirements based on the observations, enabling the team to understand the scope and goals.
• Scope of Work: Clearly outline the scope, ensuring a focused and well-defined set of objectives.
• Set the Stage by selecting tools and technologies that are needed.
• Design and Architecture: Develop a robust design and project architecture that aligns with the defined requirements and scope.

Phase 2: Design and Planning

The design and planning phase of a data engineering project is crucial for laying out the foundation of a successful and scalable solution. This phase ensures that the architecture is strategically aligned with business objectives, optimizes resource utilization, and mitigates potential risks.

Foundational Areas

• Designing the data pipeline and technology specifications like flows, coding language, data governance and tools
• Define the system architecture with cloud services for scalability like data lakes & warehouse, orchestration.
• Source control and deployment automation with CI/CD
• Using Docker containers for environment isolation to avoid deployment issues
• Infrastructure automation with Terraform or cloud CLI tools
• System monitor, notification and recovery to support operations

Phase 3: Data Pipeline and Orchestration

A data pipeline is basically a workflow of tasks that can be executed in Docker containers. The execution, scheduling, managing and monitoring of the pipeline is referred to as orchestration. In order to support the operations of the pipeline and its orchestration, we need to provision a VM and data lake.

Process:

• Get Data In: Ingest data from various sources (databases, APIs, files). Decide to get it all at once (batch) or continuously (streaming).
• Clean & Format Data: Ensure data quality and consistency. Get it ready for analysis in the right format.
• Code or No-Code: Use code (Python, SQL) or pre-built solutions.
• Run The Pipeline: Schedule tasks and run the pipeline. Track its performance to find issues.
• Store Data in the Cloud: Use data lakes (staging) for raw data and data warehouses for structured, easy-to-analyze data.
• Deploy Easily: Use containers (Docker) to deploy the pipeline anywhere.
• Monitor & Maintain: Track how the pipeline runs, fix problems, and keep it working smoothly.

Phase 4: Data Modeling and Data Warehouse

Data Lake - Analytical Data Staging

A Data Lake is an optimized storage system for Big Data scenarios. The primary function is to store the data in its raw format without any transformation. Analytical data is the data that has been extracted from a source system via a data pipeline as part of the staging data process.

Features:

• Store the data in its raw format without any transformation
• This can include structure data like CSV files, unstructured data like JSON and XML documents, or column-base data like parquet files
• Low Cost for massive storage power
• Not Designed for querying or data analysis
• It is used as external tables by a data warehouse system

Data Warehouse - Staging to Analytical Data

A Data Warehouse, Online Analytical Processing (OLAP) system, is a centralized storage system that stores integrated data from multiple sources. The system is designed to host and serve Big Data scenarios with lower operational cost than transaction databases, but higher costs than a Data Lake.

Features:

• Stores historical data in relational tables with an optimized schema, which enables the data analysis & visualization process
• Provides SQL support to query and transform the data
• Integrates external resources on Data Lakes as external tables
• The system is designed to host and serve Big Data scenarios.
• Storage is more expensive
• Offloads archived data to Data Lakes

Phase 5: Data Analysis and Visualization

How Do We Gather Insights From Data?

We leverage the principles of data analysis and visualization. Data analysis reveals patterns and trends, while visualization translates these insights into clear charts and graphs. It's the approach to turning raw data into actionable insights for smarter decision-making.

Let’s Explore More About:

• Data Analysis
  • Python and Jupyter Notebook
• Data Visualization
  • Chart Types and Design Principles
  • Code-centric with Python Graphs
  • Low-code with tools like Looker, PowerBI, Tableau

Data Analysis - Exploring Data

Data analysis is the practice of exploring data and understanding its meaning. It involves activities that can help us achieve a specific goal, such as identifying data dimensions and measures, as well as the process to identify outliers, trends, and distributions.

Methods:

• We can accomplish these activities by writing code using Python and Pandas, SQL, Jupyter Notebooks.
• We can use libraries, such as Plotly, to generate some visuals to further analyze data and create prototypes.
• The use of low-code tools also aids in the Exploratory Data Analysis (EDA) process by modeling data and using code snippets

Data Visualization - Unlock Insights

Data visualization is a practice that takes the insights derived from data analysis and presents them in a visual format. While tables with numbers on a report provide raw information, visualizations allow us to grasp complex relationships and trends at a glance with the use of charts, controls and colors.

Visualization Solutions:

• A code-centric solution involves writing programs with a language like Python, JavaScript to manage the data analysis and create the visuals

• A low-code solution uses cloud-hosted tools like Looker, PowerBI and Tableau to accelerate the data analysis and visualization by using a design approach

Summary

Throughout this session, we've explored the key stages of building a powerful cloud-based data pipeline. From identifying data sources and understanding business needs (Discovery) to designing an optimized architecture (Design & Planning), building the pipeline itself (Data Pipeline & Orchestration), and finally constructing a robust data warehouse for analysis (Data Modeling & Data Warehouse), we've equipped you with the knowledge to streamline your data flow.

By connecting your cloud pipeline to data analysis and visualization tools, you'll unlock the true power of your data, enabling you to translate insights into clear, actionable information.

We've covered a lot today, but this is just the beginning!

If you're interested in learning more about building cloud data pipelines, I encourage you to check out my book, 'Data Engineering Process Fundamentals,' part of the Data Engineering Process Fundamentals series. It provides in-depth explanations, code samples, and practical exercises to help in your learning.

Thanks for reading.

Send question or comment at Twitter @ozkary 👍 Originally published by ozkary.com

Generative AI: Create Code from GitHub User Stories - Large Language Models

Overview

This presentation explores the potential of Generative AI, specifically Large Language Models (LLMs), for streamlining software development by generating code directly from user stories written in GitHub. We delve into benefits like increased developer productivity and discuss techniques like Prompt Engineering and user story writing for effective code generation. Utilizing Python and AI, we showcase a practical example of reading user stories, generating code, and updating the corresponding story in GitHub, demonstrating the power of AI in streamlining software development.

#BuildwithAI Series

• Follow this GitHub repo during the presentation: (Give it a star and follow the project)

👉 https://github.com/ozkary/ai-engineering

• Read more information on my blog at:

YouTube Video

Video Agenda

Agenda:

• Introduction to LLMs and their Role in Code Generation
• Prompt Engineering - Guiding the LLM
• Writing User Stories for Code Generation
• Introducing Gemini AI and AI Studio
• Python Implementation - A Practical Example using VS Code
  • Reading user stories from GitHub.
  • Utilizing Gemini AI to generate code based on the user story.
  • Updating the corresponding GitHub user story with the generated code.
• Conclusion: Summarize the key takeaways of the article, emphasizing the potential of Generative AI in code creation.

Why join this session?

• Discover how Large Language Models (LLMs) can automate code generation, saving you valuable time and effort.
• Learn how to craft effective prompts that guide LLMs to generate the code you need.
• See how to write user stories that bridge the gap between human intent and AI-powered code creation.
• Explore Gemini AI and AI Studio
• Witness Code Generation in Action: Experience a live demonstration using VS Code, where user stories from GitHub are transformed into code with the help of Gemini AI.

Presentation

What are LLM Models - Not Skynet

Large Language Model (LLM) refers to a class of Generative AI models that are designed to understand prompts and questions and generate human-like text based on large amounts of training data. LLMs are built upon Foundation Models which have a focus on language understanding.

Common Tasks

• Text and Code Generation: LLMs can generate code snippets or even entire programs based on specific requirements

• Natural Language Processing (NLP): Understand and generate human language, sentiment analysis, translation

• Text Summarization: LLMs can condense lengthy pieces of text into concise summaries

• Question Answering: LLMs can access and process information from various sources to answer questions, making a great fit for chatbots

Training LLM Models - Secret Sauce

Models are trained using a combination of machine learning and deep learning. Massive datasets of text and code are collected, cleaned, and fed into complex neural networks with multiple layers. These networks iteratively learn by analyzing patterns in the data, allowing them to map inputs like user stories to desired outputs such as code generation.

Training Process:

• Data Collection: Sources from books, articles, code repositories, and online conversations

• Preprocessing: Data cleaning and formatting for the ML algorithms to understand it effectively

• Model Training: The neural network architecture is trained on the data. The network adjusts its internal parameters to learn how to map input data (user stories) to desired outputs (code snippets)

• Fine-tuning: Fine-tune models for specific tasks like code generation, by training the model on relevant data (e.g., specific programming languages, coding conventions).

Transformer Architecture - Not Autobots

Transformer is a neural network architecture that excels at processing long sequences of text by analyzing relationships between words, no matter how far apart they are. This allows LLMs to understand complex language patterns and generate human-like text.

Components

• Encoder: Process the input (use story) by using multiple encoder layers with self-attention Mechanism to analyze the relationship between words

• Decoder: Uses the encoded information and its own attention mechanism to generate the output text (like code), ensuring it aligns with the text.

• Attention Mechanism: Enables the model to effectively focus on the most important information for the task at hand, leading to improved NLP and generation capabilities.

👉 Read: Attention is all you need by Google, 2017

Prompt Engineering - What is it?

Prompt engineering is the process of designing and optimizing prompts to better utilize LLMs. Well described prompts can help the AI models better understand the context and generate more accurate responses.

Features

• Clarity and Specificity: Effective prompts are clear, concise, and specific about the task or desired response

• Task Framing: Provide background information, specifying the desired output format (e.g., code, email, poem), or outlining specific requirements

• Examples and Counter-Examples: Including relevant examples and counterexamples within the prompt can further guide the LLM

• Instructional Language: Use clear and concise instructions to improve the LLM's understanding of what information to generate

User Story Prompt:

As a web developer, I want to create a React component with TypeScript for a login form that uses JSDoc for documentation, hooks for state management, includes a "Remember This Device" checkbox, and follows best practices for React and TypeScript development so that the code is maintainable, reusable, and understandable for myself and other developers, aligning with industry standards.

Needs:

- Component named "LoginComponent" with state management using hooks (useState)
- Input fields:
    - ID: "email" (type="email") - Required email field (as username)
    - ID: "password" (type="password") - Required password field
- Buttons:
    - ID: "loginButton" - "Login" button
    - ID: "cancelButton" - "Cancel" button
- Checkbox:
    - ID: "rememberDevice" - "Remember This Device" checkbox

Generate Code from User Stories - Practical Use Case

In the Agile methodology, user stories are used to capture requirements, tasks, or a feature from the perspective of a role in the system. For code generation, developers can write user stories to capture the context, requirements and technical specifications necessary to generate code with AI.

Code Generation Flow:

• 1 User Story: Get the GitHub tasks with user story information

• 2 LLM Model: Send the user story as a prompt to the LLM Model

• 3 Generated Code: Send the generated code back to GitHub as a comment for a developer to review

👉 LLM generated code is not perfect, and developers should manually review and validate the generated code.

How does LLMs Impact Development?

LLMs accelerate development by generating code faster, leading to shorter development cycles. They also automate documentation and empower exploration of complex algorithms, fostering innovation.

Features:

• Code Completion: Analyze your code and suggest completions based on context

• Code Synthesis: Describe what you want the code to do, and the LLM can generate the code

• Code Refactoring: Analyze your code and suggest improvements for readability, performance, or best practices.

• Documentation: Generate documentation that explains your code's purpose and functionality

• Code Translation: Translate code snippets between different programming languages

👉 Security Concerns: Malicious actors could potentially exploit LLMs to generate harmful code.

What is Gemini AI?

Gemini is Google's next-generation large language model (LLM), unlocking the potential of Generative AI. This powerful tool understands and generates various data formats, from text and code to images and audio.

Components:

• Gemini: Google's next-generation multimodal LLM, capable of understanding and generating various data formats (text, code, images, audio)

• Gemini API: Integrate Gemini's into your applications with a user-friendly API

• Google AI Studio: A free, web-based platform for prototyping with Gemini aistudio.google.com

  • Experiment with prompts and explore Gemini's capabilities
    • Generate creative text formats, translate languages
  • Export your work to code for seamless integration into your projects

👉 Multimodal LLMs can handle text, images, video, code

Generative AI for Development Summary

LLM plays a crucial role in code generation by harnessing its language understanding and generative capabilities. People in roles like developers, data engineers, scientists and others can utilize AI models to swiftly generate scripts in various programming languages, streamlining their programming tasks.

Common Tasks:

• Code generation
• Natural Language Processing (NLP)
• Text summarization
• Question answering

Architecture:

• Multi-layered neural networks

• Training process

  Transformer Architecture:

• Encoder-Decoder structure
• Attention mechanism

Prompt Engineering:

• Crafting effective prompts with user stories

  Code Generation from User Stories:

  • Leveraging user stories for code generation

Thanks for reading.

Send question or comment at Twitter @ozkary

👍 Originally published by ozkary.com