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Mastering the Complexity of High-Volume Data Transmission in the Digital Ageby@akaralkar

Mastering the Complexity of High-Volume Data Transmission in the Digital Age

by Ashish KaralkarOctober 29th, 2024
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Article explaining the importance of speedy data analytics and implementation robust data infrastructure to achieve same with live streaming data
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Online data is growing exponentially every day. Businesses must stay ahead of the curve and be competitive, which can be achieved by steering away from traditional. Information should be available to executives as early as possible to keep the edge. Ensuring the data is transmitted correctly and reliably every time can be tricky. It is also critical for businesses to have access to the data across all departments.


It is essential to process the data as soon as it comes in to make it quicker to turn data into insights.


Apache Kafka, along with Apache Kafka Streams or Apache Flink, is turning out to be the best bet for processing, storing, and making streaming data readily available across different business units.

Apache Kafka at the Core

A key element in today's data streaming infrastructure is Kafka Queues. It is an effective messaging system that follows a publish-and-subscribe approach and is well known for its dependability and ability to withstand faults gracefully. This system is expertly designed to handle message volumes, per second and supports applications that rely on real-time data streaming.


Apache Kafka data queues are essential for tailoring to diverse industry requirements. Kafka supports different industry scenarios, especially real-time data streaming, and ensures data accessibility for business functions.


In the case of real-time streaming data, each data event can be treated as a single segment, parsed to various topics, and stored on Kafka servers. e.g., for a grocery store chain, a user e-commerce transaction can be parsed into user details, grocery store location, amount of transaction, inventory sold, and all of this in a fraction of seconds of the event, enabling the business to run analytics on a live-stream of data and re-route the exhausting inventory to the appropriate store thereby making sure stores needing more stock has it than it is sitting idle on the shelf for other stores.


Apache Kafka's role extends beyond real-time streaming data. It is a vital pillar in integrating data infrastructure between business units or company mergers/acquisitions. Instead of copying data multiple times, Kafka serves as a central hub where all business components can produce data (Producers), and the business units that need it can consume it (Consumers).


Kafka as a central data store helps avoid the need for repetitive engineering work by different business units to consume the same data and if needed modify on the fly using Kafka Streams or Flink thereby simplifying the data integration process. With the introduction of KRAFT in Apache Kafka, eliminating the need for a quorum manager zookeeper cluster, the cost of operating Kafka queues is even less with the same performance.

Reliability, Scalability, and Security

The challenge extends beyond speed; reliability, scalability, and security are equally vital. Data transmission systems should be designed for speed but other aspects of the systems can not be underestimated. These systems are required to ensure reliable delivery of millions of messages. Furthermore, scalability is imperative to handle the increasing data volumes.


Reliability:

A system that is high-speed but not reliable is of no use. An effective system requires monitoring and automating recovery procedures while also planning to handle the increasing amount of data effectively. It is crucial for reliability to detect and address issues before they worsen through monitoring. A monitoring strategy covering all aspects from hardware to software, to business operations, is essential.


Kafka is a memory-hogging system, and enough memory should be available, as without it, the system will default to an operating system swap, thereby degrading performance. On the software level, fault tolerance is essential, which can be achieved by ensuring a minimum replication factor of three (three copies of data in a cluster).


Rack diversity ensures that all three copies of data are on different rack nodes in the Kafka Cluster, thereby reducing the risk of data loss in case of a rack failure. Auto rebalancing of data based on cluster performance can be achieved using Kafka Cruise Control based on various target thresholds e.g., network bandwidth and the number of messages in or out.


In the business process, enough monitoring should be added to ensure producer and consumer instances are live and able to communicate with Kafka brokers. Multiple instances of producer and consumer applications need to be implemented to ensure high availability.


Scalability:

The Kafka clusters must be able to handle parallel processing for both reading and writing. If the cluster struggles to keep up with read requests, it needs more resources per server - Vertical Scaling. This means using higher CPU and RAM configuration servers to handle the increased workload.


If the cluster is having difficulty handling write requests, the cluster needs additional servers - Horizontal Scaling. This involves adding more servers to the cluster to share the workload. Kafka is a distributed system, scaling vertically or horizontally is a transparent operation for applications as long as applications have implemented retry on certain errors.


Security:

In today's digital world, data security is a top priority. Data must be encrypted at rest and in transit using the TLS protocol in Kafka. Robust user access control can be established as a two-step process using the Authentication and Authorization approach to ensure secure access. For the first step, Kafka offers multiple authentication mechanisms such as mutual TLS (mTLS) and Simple Authentication and Security Layer (SASL) to ensure that only permitted applications can authenticate to the cluster.


mTLS encryption makes sure that both the client and the server authenticate each other, while SASL provides a framework for adding authentication support to connection-based protocols. For the second step, Kafka offers authorization on a topic level with appropriate privileges, such as read or write access.


Overall, the Apache Kafka Ecosystem provides robust data infrastructure for processing and securely storing live data while making it readily available for all business units without reinventing the wheel of data processing.