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August 22, 2024

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SQL Server 2022: A Deep Dive into the APPROX_PERCENTILE_CONT Function with JBDB Database

SQL Server 2022 introduces several new features, one of the most exciting being the APPROX_PERCENTILE_CONT function. This function allows for efficient and approximate calculation of percentiles in large datasets, which can be particularly useful for analytics and data-driven decision-making. In this blog, we will explore the APPROX_PERCENTILE_CONT function in detail, using the JBDB database for practical demonstrations. We’ll start with a business use case, dive into the function’s capabilities, and provide a range of T-SQL queries for you to try. Let’s get started! 🚀

Business Use Case: Customer Transaction Analysis 💼

Consider a retail company that wants to analyze customer spending behavior. The company has a vast amount of transaction data stored in the JBDB database. To optimize marketing strategies and tailor promotions, they want to identify spending patterns across different customer segments.

For example, the company might want to know the 90th percentile of spending amounts to target high-value customers with exclusive offers. Calculating this percentile accurately in a large dataset can be resource-intensive. The APPROX_PERCENTILE_CONT function offers a solution by providing an approximate, yet efficient, calculation of percentiles.

Understanding the APPROX_PERCENTILE_CONT Function 📊

The APPROX_PERCENTILE_CONT function is designed to compute approximate percentile values for a set of data. This function is particularly useful when dealing with large datasets, as it offers a performance advantage by using approximate algorithms.

Syntax:

APPROX_PERCENTILE_CONT ( percentile ) WITHIN GROUP ( ORDER BY numeric_expression )

percentile: A value between 0 and 1 that specifies the desired percentile.
numeric_expression: The column or expression to calculate the percentile on.

Example 1: Basic Usage 🌟

Let’s calculate the 90th percentile of customer transaction amounts.

Setup:

USE JBDB;
GO

CREATE TABLE CustomerTransactions (
    TransactionID INT PRIMARY KEY,
    CustomerID INT,
    TransactionAmount DECIMAL(18, 2),
    TransactionDate DATE
);

INSERT INTO CustomerTransactions (TransactionID, CustomerID, TransactionAmount, TransactionDate)
VALUES
(1, 101, 50.00, '2023-01-15'),
(2, 102, 150.00, '2023-01-16'),
(3, 103, 300.00, '2023-01-17'),
(4, 101, 75.00, '2023-01-18'),
(5, 104, 200.00, '2023-01-19'),
(6, 105, 125.00, '2023-01-20'),
(7, 106, 400.00, '2023-01-21'),
(8, 102, 175.00, '2023-01-22');
GO

Query to Calculate 90th Percentile:

SELECT APPROX_PERCENTILE_CONT(0.90) WITHIN GROUP (ORDER BY TransactionAmount) AS Approx90thPercentile
FROM CustomerTransactions;

This result indicates that 90% of transactions are below $375. This insight can help the company focus on high-value customers who spend above this threshold.

Example 2: Analyzing Different Percentiles 🔍

Let’s calculate different percentiles to understand the distribution of transaction amounts.

Query to Calculate Multiple Percentiles:

SELECT 
    APPROX_PERCENTILE_CONT(0.25) WITHIN GROUP (ORDER BY TransactionAmount) AS Approx25thPercentile,
    APPROX_PERCENTILE_CONT(0.50) WITHIN GROUP (ORDER BY TransactionAmount) AS Approx50thPercentile,
    APPROX_PERCENTILE_CONT(0.75) WITHIN GROUP (ORDER BY TransactionAmount) AS Approx75thPercentile,
    APPROX_PERCENTILE_CONT(0.90) WITHIN GROUP (ORDER BY TransactionAmount) AS Approx90thPercentile
FROM CustomerTransactions;

These results provide a clear view of the transaction distribution, helping the company to tailor marketing strategies for different customer segments.

Comparing Percentile Results:

Compare approximate and exact percentile calculations for the 90th percentile:

SELECT 
    APPROX_PERCENTILE_CONT(0.90) WITHIN GROUP (ORDER BY TransactionAmount) AS Approx90thPercentile,
    PERCENTILE_CONT(0.90) WITHIN GROUP (ORDER BY TransactionAmount) OVER () AS Exact90thPercentile
FROM CustomerTransactions
group by TransactionAmount;

Segmenting Customers by Spending:

Identify customers whose spending is in the top 10%:

SELECT CustomerID, TransactionAmount
FROM CustomerTransactions
WHERE TransactionAmount >= (SELECT APPROX_PERCENTILE_CONT(0.90) WITHIN GROUP (ORDER BY TransactionAmount)
                             FROM CustomerTransactions);

Analyzing Spending Patterns Over Time:

Calculate monthly spending percentiles to identify trends:

SELECT 
    DATEPART(MONTH, TransactionDate) AS Month,
    APPROX_PERCENTILE_CONT(0.50) WITHIN GROUP (ORDER BY TransactionAmount) AS MedianTransaction
FROM CustomerTransactions
GROUP BY DATEPART(MONTH, TransactionDate)
ORDER BY Month;

Combining Percentiles with Other Aggregations:

Find the average transaction amount for each percentile group:

SELECT 
    PercentileGroup,
    AVG(TransactionAmount) AS AvgTransactionAmount
FROM (
    SELECT 
        TransactionAmount,
        NTILE(4) OVER (ORDER BY TransactionAmount) AS PercentileGroup
    FROM CustomerTransactions
) AS SubQuery
GROUP BY PercentileGroup;

Conclusion 🏁

The APPROX_PERCENTILE_CONT function in SQL Server 2022 is a powerful tool for efficiently computing approximate percentiles in large datasets. By using this function, businesses can gain valuable insights into data distributions and make informed decisions based on these insights. Whether you’re analyzing customer spending, sales trends, or any other data, the APPROX_PERCENTILE_CONT function offers a quick and efficient way to understand your data.

Happy querying! 😄

For more tutorials and tips on SQL Server, including performance tuning and database management, be sure to check out our JBSWiki YouTube channel.

Thank You,
Vivek Janakiraman

Disclaimer:
The views expressed on this blog are mine alone and do not reflect the views of my company or anyone else. All postings on this blog are provided “AS IS” with no warranties, and confers no rights.

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Vivek Janakiraman

Posted on

August 21, 2024

Posted under

SQL Server 2022

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SQL Server 2022: Unleashing the Power of the GENERATE_SERIES Function

In SQL Server 2022, the introduction of the GENERATE_SERIES function marks a significant enhancement, empowering developers and analysts with a flexible and efficient way to generate sequences of numbers. This feature, akin to similar functions in other database systems, simplifies tasks involving sequence generation, such as creating time series data, generating test data, and more.

In this blog, we’ll explore the GENERATE_SERIES function in detail, using the JBDB database to demonstrate its capabilities. We’ll start with a practical business use case, followed by a comprehensive guide on how to use the function. Let’s dive in! 🌟

Business Use Case: Sales Forecasting 📈

Imagine you are working for a retail company, and your task is to generate a sales forecast for the next year. You have historical sales data and need to project future sales based on trends. A crucial step in this process is to create a series of dates representing each day of the next year, which will serve as the basis for the forecast.

The GENERATE_SERIES function can be a game-changer here, allowing you to quickly generate a range of dates without resorting to complex loops or recursive queries.

Introducing the `GENERATE_SERIES` Function 🛠️

The GENERATE_SERIES function generates a series of numbers or dates. Its syntax is straightforward:

GENERATE_SERIES(start, stop, step)

start: The starting value of the sequence.
stop: The ending value of the sequence.
step: The increment value between each number in the series.

Let’s see this in action with some practical examples!

Example 1: Basic Numeric Series 🔢

To generate a series of numbers from 1 to 10:

SELECT value
FROM GENERATE_SERIES(1, 10, 1);

Example 2: Date Series for Forecasting 📅

To generate a series of dates for each day of the next year, starting from January 1, 2023:

SELECT CAST(value AS DATE) AS ForecastDate
FROM GENERATE_SERIES('2023-01-01', '2023-12-31', 1);

Generating a Series of Dates Using a CTE 📅

Since GENERATE_SERIES supports numeric sequences only, we use a recursive CTE to generate a series of dates. Here’s how to create a series of dates for the year 2023:

-- Create a recursive CTE to generate a series of dates
WITH DateSeries AS (
    -- Anchor member: start date
    SELECT CAST('2023-01-01' AS DATE) AS ForecastDate
    UNION ALL
    -- Recursive member: add one day to the previous date
    SELECT DATEADD(DAY, 1, ForecastDate)
    FROM DateSeries
    WHERE ForecastDate < '2023-12-31'
)
-- Query to select the generated dates
SELECT ForecastDate
FROM DateSeries
OPTION (MAXRECURSION 0); -- Remove recursion limit

Implementing the Use Case: Sales Forecasting 📊

Let’s apply the GENERATE_SERIES function to our sales forecasting scenario. Suppose we have a table Sales in the JBDB database with historical sales data. Our goal is to project future sales for each day of the next year.

Step 1: Creating the JBDB and Sales Table 🏗️

First, we create the JBDB database and the Sales table:

CREATE DATABASE JBDB;
GO

USE JBDB;
GO

CREATE TABLE Sales (
    SaleDate DATE,
    Amount DECIMAL(10, 2)
);

Step 2: Inserting Historical Data 📥

Next, let’s insert some historical data into the Sales table:

INSERT INTO Sales (SaleDate, Amount)
VALUES
('2022-01-01', 100.00),
('2022-01-02', 150.00),
('2022-01-03', 200.00),
-- Additional data...
('2022-12-31', 250.00);

Step 3: Generating Future Dates and Forecasting 📅🔮

Now, we use GENERATE_SERIES to generate future dates and join it with our historical data to create a sales forecast:

-- Generate a series of future dates
WITH DateSeries AS (
    SELECT CAST('2023-01-01' AS DATE) AS ForecastDate
    UNION ALL
    SELECT DATEADD(DAY, 1, ForecastDate)
    FROM DateSeries
    WHERE ForecastDate < '2023-12-31'
),
-- Combine with historical sales data
SalesForecast AS (
    SELECT
        f.ForecastDate,
        ISNULL(s.Amount, 0) AS HistoricalAmount
    FROM
        DateSeries f
        LEFT JOIN Sales s ON f.ForecastDate = s.SaleDate
)
-- Project future sales
SELECT
    ForecastDate,
    HistoricalAmount,
    -- Simple projection logic (for demonstration)
    HistoricalAmount * 1.05 AS ProjectedAmount
FROM SalesForecast
OPTION (MAXRECURSION 0); -- Remove recursion limit

In this query:

We generate a series of dates for the year 2023 using GENERATE_SERIES.
We join these dates with the historical sales data to create a comprehensive sales forecast.
A simple projection logic is applied, assuming a 5% increase in sales.

Generate a Series of Numbers with Custom Step Size

Generate a sequence of numbers from 1 to 50 with a step size of 5:

-- Generate a sequence of numbers with a custom step size
SELECT value
FROM GENERATE_SERIES(1, 50, 5);

Generate a Series of Dates with Custom Step Size

Generate a series of dates from today to 30 days into the future with a step size of 5 days:

-- Generate a series of dates with a custom step size (5 days)
WITH DateSeries AS (
    SELECT DATEADD(DAY, value * 5, CAST(GETDATE() AS DATE)) AS ForecastDate
    FROM GENERATE_SERIES(0, 6, 1) -- 0 to 6 will generate 7 dates
)
SELECT ForecastDate
FROM DateSeries;

Generate a Series of Random Numbers

Generate a series of random numbers between 1 and 100:

-- Generate a series of random numbers between 1 and 100
SELECT ABS(CHECKSUM(NEWID())) % 100 + 1 AS RandomNumber
FROM GENERATE_SERIES(1, 10, 1); -- Generate 10 random numbers

Generate a Series of Time Intervals

Generate a series of time intervals (every 15 minutes) for one hour:

-- Generate a series of time intervals (15 minutes) for one hour
WITH TimeSeries AS (
    SELECT DATEADD(MINUTE, value * 15, CAST('2024-01-01 00:00:00' AS DATETIME)) AS TimeStamp
    FROM GENERATE_SERIES(0, 3, 1) -- 0 to 3 will generate 4 intervals
)
SELECT TimeStamp
FROM TimeSeries;

Generate a Series of Sequential IDs

Generate a series of sequential IDs from 1001 to 1010:

-- Generate a sequence of sequential IDs
SELECT value + 1000 AS SequentialID
FROM GENERATE_SERIES(1, 10, 1);

Generate a Series of Numeric Values with Non-Uniform Steps

Generate a series of numbers with varying steps (e.g., 1, 2, 4, 8, …):

-- Generate a series of numbers with varying steps (powers of 2)
WITH NumberSeries AS (
    SELECT 1 AS value
    UNION ALL
    SELECT value * 2
    FROM NumberSeries
    WHERE value < 64
)
SELECT value
FROM NumberSeries
OPTION (MAXRECURSION 0);

Generate a Series of Dates with Monthly Intervals

Generate a series of dates with a monthly interval for one year:

-- Generate a series of dates with monthly intervals for one year
WITH MonthSeries AS (
    SELECT DATEADD(MONTH, value, CAST('2024-01-01' AS DATE)) AS MonthStart
    FROM GENERATE_SERIES(0, 11, 1) -- 0 to 11 will generate 12 months
)
SELECT MonthStart
FROM MonthSeries;

Generate a Series of Numbers and Calculate Cumulative Sum

Generate a series of numbers and calculate their cumulative sum:

-- Generate a series of numbers and calculate the cumulative sum
WITH NumberSeries AS (
    SELECT value
    FROM GENERATE_SERIES(1, 10, 1)
),
CumulativeSum AS (
    SELECT
        value,
        SUM(value) OVER (ORDER BY value) AS CumulativeSum
    FROM NumberSeries
)
SELECT value, CumulativeSum
FROM CumulativeSum;

Generate a Series of Custom Random Dates

Generate a series of random dates within a specific range:

— Generate a series of random dates within a specific range
WITH RandomDates AS (
SELECT DATEADD(DAY, ABS(CHECKSUM(NEWID())) % 365, CAST(‘2024-01-01’ AS DATE)) AS RandomDate
FROM GENERATE_SERIES(1, 10, 1) — Generate 10 random dates
)
SELECT RandomDate
FROM RandomDates;

Generate a Series of Numbers and Create Custom Labels

Generate a series of numbers and create custom labels:

— Generate a series of numbers and create custom labels
SELECT value AS Number, ‘Label_’ + CAST(value AS VARCHAR(10)) AS CustomLabel
FROM GENERATE_SERIES(1, 10, 1);

Conclusion 🌟

The GENERATE_SERIES function in SQL Server 2022 is a versatile tool that can significantly simplify the generation of sequences, whether for numeric ranges or date series. Its applications range from creating time series data for analytics to generating test data for development and testing purposes.

By leveraging GENERATE_SERIES, businesses can streamline their data workflows, enhance forecasting accuracy, and improve decision-making processes. Whether you’re a database administrator, developer, or data analyst, this function is a valuable addition to your SQL toolkit.

Feel free to experiment with GENERATE_SERIES and explore its potential in your projects! 🎉

For more tutorials and tips on SQL Server, including performance tuning and database management, be sure to check out our JBSWiki YouTube channel.

Thank You,
Vivek Janakiraman

Posted by

Vivek Janakiraman

Posted on

July 30, 2024

Posted under

SQL Server 2022

Comments

SQL Server 2022 STRING_SPLIT Enhancements: A Deep Dive with JBDB Database

In SQL Server 2022, the STRING_SPLIT function has been enhanced, making it a powerful tool for parsing and handling delimited strings. This blog will provide an exhaustive overview of these enhancements, using the JBDB database for demonstrations. We’ll explore a detailed business use case, delve into the new features, and provide T-SQL queries for you to practice and master the updated STRING_SPLIT function. Let’s dive in! 🌊

Business Use Case: Customer Preferences Analysis 🛍️

Imagine you’re working for an e-commerce company that tracks customer preferences for various product categories. Each customer’s preference is stored as a comma-separated string in the database. Your task is to analyze these preferences to offer personalized recommendations and optimize the marketing strategy.

For instance, the data might look like this:

Customer 1: Electronics,Books,Toys
Customer 2: Groceries,Fashion,Electronics
Customer 3: Books,Beauty,Fashion

With the enhancements in STRING_SPLIT in SQL Server 2022, you can efficiently parse these strings and analyze the data. Let’s explore how!

STRING_SPLIT Enhancements in SQL Server 2022 🚀

In SQL Server 2022, STRING_SPLIT has been enhanced to include:

Ordinal Output: A new parameter, ordinal, can now be specified to include the position of each substring in the original string.
Improved Performance: Enhanced indexing capabilities for better performance in large datasets.

Syntax:

STRING_SPLIT ( string, separator [, enable_ordinal ] )

string: The input string to be split.
separator: The delimiter character.
enable_ordinal: Optional; specifies whether to include the ordinal position of each substring (0 or 1).

Example 1: Basic Usage 🌟

Let’s start with a simple example to see the new ordinal feature in action.

Setup:

USE JBDB;
GO

CREATE TABLE CustomerPreferences (
    CustomerID INT PRIMARY KEY,
    Preferences VARCHAR(100)
);

INSERT INTO CustomerPreferences (CustomerID, Preferences)
VALUES
(1, 'Electronics,Books,Toys'),
(2, 'Groceries,Fashion,Electronics'),
(3, 'Books,Beauty,Fashion');
GO

Query with `STRING_SPLIT`:

SELECT CustomerID, value, ordinal
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1);

This output shows the customer preferences along with their order of appearance. The ordinal column is a new addition in SQL Server 2022, providing valuable information about the sequence of items.

Example 2: Analyzing Preferences 🔍

Now, let’s say we want to find out the most popular categories among all customers.

Query to Find Most Popular Categories:

SELECT value AS Category, COUNT(*) AS Count
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
GROUP BY value
ORDER BY Count DESC;

From the output, we can see that ‘Electronics’, ‘Books’, and ‘Fashion’ are the most popular categories. This data can be used to tailor marketing campaigns and inventory management.

Extracting Categories Based on Position:

Find customers whose second preference is ‘Fashion’:

SELECT CustomerID
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
WHERE ordinal = 2 AND value = 'Fashion';

Counting Unique Categories:

Count the number of unique categories preferred by customers:

SELECT COUNT(DISTINCT value) AS UniqueCategories
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1);

Combining STRING_SPLIT with Other Functions:

Find the length of each preference category string:

SELECT CustomerID, value, LEN(value) AS Length
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1);

Analyzing Preferences by Customer:

Count the number of preferences each customer has:

SELECT CustomerID, COUNT(*) AS PreferenceCount
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
GROUP BY CustomerID;

Extracting Values by Ordinal Position:

Identify customers whose first preference is ‘Electronics’:

SELECT CustomerID
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
WHERE ordinal = 1 AND value = 'Electronics';

Finding Specific Ordinal Positions:

Retrieve all customers whose third preference includes ‘Books’:

SELECT CustomerID
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
WHERE ordinal = 3 AND value = 'Books';

Filtering Based on Multiple Conditions:

Find customers who have ‘Books’ in any position and ‘Fashion’ as the last preference:

SELECT CustomerID
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
GROUP BY CustomerID
HAVING SUM(CASE WHEN value = 'Books' THEN 1 ELSE 0 END) > 0
   AND MAX(CASE WHEN value = 'Fashion' THEN ordinal ELSE 0 END) = COUNT(*);

Analyzing Distribution of Preferences:

Determine the number of customers who have each category as their first preference:

SELECT value AS FirstPreference, COUNT(*) AS Count
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
WHERE ordinal = 1
GROUP BY value
ORDER BY Count DESC;

Combining STRING_SPLIT with String Functions:

Find the customers with the longest category name in their preferences:

SELECT CustomerID, value, LEN(value) AS Length
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
ORDER BY Length DESC;

Using STRING_SPLIT for Data Transformation:

Convert customer preferences into a single concatenated string with a different delimiter:

SELECT CustomerID, STRING_AGG(value, '|') AS ConcatenatedPreferences
FROM CustomerPreferences
CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
GROUP BY CustomerID;

Analyzing Preference Patterns:

Find the most common pattern of the first two preferences:

WITH FirstTwoPreferences AS (
    SELECT CustomerID, STRING_AGG(value, ',') WITHIN GROUP (ORDER BY ordinal) AS Pattern
    FROM CustomerPreferences
    CROSS APPLY STRING_SPLIT(Preferences, ',', 1)
    WHERE ordinal <= 2
    GROUP BY CustomerID
)
SELECT Pattern, COUNT(*) AS Count
FROM FirstTwoPreferences
GROUP BY Pattern
ORDER BY Count DESC;

Conclusion 🏁

The enhancements in SQL Server 2022’s STRING_SPLIT function, particularly the introduction of the ordinal parameter, provide powerful tools for handling and analyzing delimited strings. Whether you’re working with customer data, logs, or any form of delimited information, these enhancements can streamline your processes and deliver valuable insights.

Happy querying! 😄

For more tutorials and tips on SQL Server, including performance tuning and database management, be sure to check out our JBSWiki YouTube channel.

Thank You,
Vivek Janakiraman

SQL Server 2022: A Deep Dive into the APPROX_PERCENTILE_CONT Function with JBDB Database

Business Use Case: Customer Transaction Analysis 💼

Understanding the APPROX_PERCENTILE_CONT Function 📊

Syntax:

Example 1: Basic Usage 🌟

Setup:

Query to Calculate 90th Percentile:

Example 2: Analyzing Different Percentiles 🔍

Query to Calculate Multiple Percentiles:

Comparing Percentile Results:

Segmenting Customers by Spending:

Analyzing Spending Patterns Over Time:

Combining Percentiles with Other Aggregations:

Conclusion 🏁

SQL Server 2022: Unleashing the Power of the GENERATE_SERIES Function

Business Use Case: Sales Forecasting 📈

Introducing the GENERATE_SERIES Function 🛠️

Example 1: Basic Numeric Series 🔢

Example 2: Date Series for Forecasting 📅

Generating a Series of Dates Using a CTE 📅

Implementing the Use Case: Sales Forecasting 📊

Step 1: Creating the JBDB and Sales Table 🏗️

Step 2: Inserting Historical Data 📥

Step 3: Generating Future Dates and Forecasting 📅🔮

Generate a Series of Numbers with Custom Step Size

Generate a Series of Dates with Custom Step Size

Generate a Series of Random Numbers

Generate a Series of Time Intervals

Generate a Series of Sequential IDs

Generate a Series of Numeric Values with Non-Uniform Steps

Generate a Series of Dates with Monthly Intervals

Generate a Series of Numbers and Calculate Cumulative Sum

Generate a Series of Custom Random Dates

Generate a Series of Numbers and Create Custom Labels

Conclusion 🌟

SQL Server 2022 STRING_SPLIT Enhancements: A Deep Dive with JBDB Database

Business Use Case: Customer Preferences Analysis 🛍️

STRING_SPLIT Enhancements in SQL Server 2022 🚀

Syntax:

Example 1: Basic Usage 🌟

Setup:

Query with STRING_SPLIT:

Example 2: Analyzing Preferences 🔍

Query to Find Most Popular Categories:

Extracting Values by Ordinal Position:

Finding Specific Ordinal Positions:

Filtering Based on Multiple Conditions:

Analyzing Distribution of Preferences:

Combining STRING_SPLIT with String Functions:

Using STRING_SPLIT for Data Transformation:

Analyzing Preference Patterns:

Conclusion 🏁

Introducing the `GENERATE_SERIES` Function 🛠️

Query with `STRING_SPLIT`: