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NoSQL: System Design Cheat Sheetby@therealone
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8,127 reads

NoSQL: System Design Cheat Sheet

by Denis LarionovOctober 30th, 2023
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I would like to talk about different types of NoSQL databases and show for what tasks they are used. There are several types of NoSQL databases, each with its own characteristics and used in different scenarios.

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I would like to talk about different types of NoSQL databases and show for what tasks they are used. There are several types of NoSQL databases, each with its own characteristics and used in different scenarios.

Key-Value Databases

In this type of database, data is stored as key-value pairs. The key is unique and is used to access the corresponding value. Examples of such databases include Redis and Riak.


Use cases include:

  • Caching: Redis and other key-value stores are used for caching frequently accessed data, reducing the load on slower databases and significantly improving application performance.


  • Session Management: Key-value stores help manage user sessions on websites, storing session information such as login data and user preferences.


  • Real-time and Analytics Applications: Key-value stores are well-suited for storing real-time updating data, such as performance indicators, statistics, and metrics, and provide fast access to up-to-date information.


  • Counters and Statistics: Key-value stores efficiently store statistics for website visits, counters, likes, retweets, and other metrics where fast data updates are required.


  • Geodata and Geolocation: Key-value stores are used to store location information, such as geolocation coordinates and points of interest on a map.


  • Task Queue Implementation: Key-value stores can be used to create task queue processing systems, where keys represent tasks and values represent data for processing.


  • Internet of Things (IoT): Key-value stores allow managing and storing data from a multitude of IoT sensors and devices, where keys and values can represent measurements and parameters.


  • Configuration Storage: Key-value stores allow storing and updating application and system settings.


Key-value databases provide fast data access by key, which is their main advantage.

Document Databases

Document databases store data in document formats such as JSON or XML. Examples of such databases include MongoDB and CouchDB. They provide a flexible data schema and allow for storing and retrieving complex documents.


They are characterized by flexibility and the ability to store semi-structured data in document format. They find application in various scenarios:


  • Content Management: Document databases efficiently store and manage content such as articles, images, videos, and audio. This is particularly useful in content management systems (CMS) and digital libraries.


  • Analytics and Reporting: Due to their flexibility, document databases allow storing and analyzing diverse data, which is useful for creating reports and analytical tools.


  • User Management and Authentication: Document databases simplify user management, roles, and authentication by allowing storage of relevant information.


  • E-commerce and Online Stores: Document databases effectively store information about products, orders, and customers.


  • Gaming Industry: In computer games and virtual worlds, document databases are used to store game objects, character settings, and player achievements.


  • Accounting and Task Management Systems: Document databases are suitable for managing tasks, projects, and to-do lists. Documents can represent tasks and their related attributes.


  • Internet of Things (IoT): Document databases are used to store data from sensors and IoT devices, as they can store various types of data.


  • Support for Applications with Evolving Schemas: The flexibility of document databases allows applications to efficiently work with data whose schema may change over time.


  • Event Logs and Audit: Document databases can be used for event logging, auditing, and analyzing action logs.


Document databases excel where data can be semi-structured, or its schema may change over time.

Columnar Databases

Columnar databases store data in columns rather than rows, allowing for efficient processing of large volumes of data and analytical queries. Examples of databases of this type include Vertica and Clickhouse.


Columnar databases are widely used in big data analytics, time series storage, and accounting systems.


They have unique features that make them suitable for various scenarios and applications:

  • Analytics and Big Data Warehouses: Systems like Vertica are often used for analyzing large volumes of data. They provide high read-and-write performance, which is particularly useful for big data warehouses and analytics systems.


  • Time Series Accounting Systems: Columnar databases can be efficient in storing and analyzing time series data such as event logs, performance metrics, and monitoring systems.


  • Internet of Things (IoT): In the Internet of Things networks, where hundreds and thousands of devices generate data streams, columnar databases are capable of processing and storing data in real-time.


  • Real-time Systems: Thanks to their high performance and scalability, columnar databases are used in real-time systems, including event processing and transaction processing systems.


  • Customer Data Accounting and Management Systems: Columnar databases can store data about customers, their orders, preferences, and interactions with the company.


  • Social Networks and Recommendation Systems: Columnar databases are used to store relationships between users, their actions, and recommendations.


  • Media Content Storage and Analysis Systems: They can store and process large volumes of images, videos, and audio data.


  • Version Control and Archiving Systems: The data structure of columnar databases allows for storing and tracking changes in documents and data with the ability to restore previous versions.


  • Financial Systems and Trading: In financial applications, columnar databases can store quotes, transactions, operational history, and other data.


  • Monitoring and Audit Systems: The ability to store and analyze event and audit log data makes them useful in security and monitoring systems.


Columnar databases provide high performance and scalability, making them an ideal choice for applications that require processing large volumes of data and fast access to them.

Wide-Column Stores

Many people confuse columnar databases with wide-column stores. They have some similarities but also significant differences. Here are the main differences between them:


Wide-Column Stores:

  • Data Model: Wide-Column Stores use a data model based on column families. Each family can contain different columns, and data rows can contain different families.


  • Schema Flexibility: Wide-Column Stores usually have a high degree of schema flexibility. Column families and columns themselves can be dynamically added without changing the entire schema.


  • Read Performance: Wide-Column Stores provide high read performance, especially for queries that require reading a large number of columns.


Columnar Databases:

  • Data Model: Columnar Databases use a data model where each column represents a separate data fragment. This allows for efficient data compression and compact storage.


  • Data Compression: Columnar Databases usually provide data compression mechanisms, making them suitable for storing large volumes of information.


  • Write Performance: Columnar Databases often provide high write performance. They are good for applications with a high write load.


The rapid development of NoSQL database technologies has led to the emergence of different types of databases, each with its own characteristics and areas of application. It is important to consider that the choice between Wide-Column Stores and Columnar Databases depends on the specific system and the task at hand.

Graph Databases

Graph databases are designed to store and process data organized in graph structures. They model data as a graph, where nodes represent objects and edges represent relationships between them. Examples of such databases include Neo4j and Amazon Neptune.


They find applications in many areas where connections and relationships between data play an important role. Here are some areas of their application:


Social networks: Graph databases are ideal for storing information about users, their connections, friends, and interactions in social networks.


  • Recommendation systems: Analyzing user preferences and relationships allows for personalized recommendations, including products, music, and movies.


  • Geospatial data: Graph databases are well-suited for storing and analyzing geospatial data, such as maps, routes, and locations.


  • Bioinformatics and genomics: Graph databases are used for analyzing genetic data, gene and protein relationships, as well as metabolic pathways.


  • Fraud and security: Analyzing connections between events and users helps identify anomalies and potential threats in security and monitoring.


  • E-commerce recommendation systems: Graph databases can be used for analyzing consumer behavior and providing shopping recommendations.


  • Network and transportation system analysis: Graph databases help model and optimize networks, such as transportation routes and telecommunication systems.


  • Relationship management systems and network analysis: Graph databases are applied in analyzing relationships between entities, both in forensic and sociological contexts.


  • Logistics and supply chain management: Graph databases can help optimize supply chains and delivery routes.


Graph databases are perfect for scenarios where it is important to model and analyze complex relationships between data or where the data itself represents a graph structure.

Time Series Databases

Time series databases are specialized in storing and analyzing time-based data, such as sensor data or logs. They provide efficient storage and fast access to ordered data. Examples of such databases include InfluxDB and TimescaleDB.


Time series databases are used in various fields where analysis of time-based data is required. Here are some areas of application for time series databases:


  • Internet of Things (IoT): Time series databases are used for collecting and analyzing data from multiple sensors and devices in real-time.


  • Finance and Financial Markets: They are applied for analyzing financial time series data, such as stock quotes, currency exchange rates, and asset valuation time series.


  • Monitoring and Performance Analytics: Used for monitoring the performance of computer systems, servers, networks, and applications.


  • Healthcare and Medicine: They are used for patient monitoring, collection of medical data, and analysis of biometric indicators.


  • Telecommunications: For network monitoring, quality of communication, load analysis, and traffic analysis.


  • Energy: For accounting and monitoring energy consumption, analysis of production and distribution data.


  • Meteorology and Climatology: Time series databases are used for storing meteorological data and analyzing climate indicators.


  • Logistics and Transportation: For monitoring and optimizing logistics and transportation operations, including route tracking and vehicle status.


  • Marketing Analytics: Used for analyzing consumer behavior data, advertising campaigns, and marketing effectiveness.


  • Security and Monitoring Systems: Time series databases enable event and action tracking for security and monitoring purposes.


  • Accounting and Auditing Systems: They are used to record events and audits, as well as to ensure data integrity.


Time series databases provide the ability to store and analyze data over time, making them important for a variety of fields where tracking, analyzing, and forecasting data changes are required.


Each type of NoSQL database is designed for different usage scenarios and has its unique characteristics. The choice of a specific database depends on the requirements of your project and the characteristics of your data.


It is also important to highlight the significant role of relational databases in the context of structured data, where maintaining data integrity and relationships is critical.


Relational databases have powerful capabilities for processing and analyzing data using SQL queries and provide reliability and data consistency.


Therefore, when choosing a database for your project, it is important to consider the characteristics and requirements of the database itself, as well as the specifics of your data and usage scenarios.


It is important to note that relational databases are widely used in various industries, including finance, commerce, healthcare, and others. They provide solid guarantees of data integrity and reliability, as well as support a wide range of features for data analysis and processing.


However, in recent years, with the development of NoSQL databases, new opportunities have emerged for processing and storing data in different formats and structures.


The flexibility and scalability of NoSQL databases allow for efficient handling of large volumes of data and modeling complex relationships.


Therefore, when choosing between relational and NoSQL databases, it is important to consider the requirements of your project, data volume, complexity of relationships, and usage scenarios.


Combining different types of databases can also be an effective approach for optimal solutions to data processing and storage tasks.