PptxGenJS Presentation

Chapter 1: Evolution of Agriculture Through Industrial Revolutions.

Introduction. The industrial revolutions shaped the world and revolutionized agriculture. From the mechanization of textile manufacturing to digitalization, these transformations have significantly impacted farming practices and productivity..

First Industrial Revolution (1760-1830). Mechanization.

Second Industrial Revolution (Late 19th - Early 20th Century).

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Fourth Industrial Revolution (Ongoing). 1. Industry 4.0.

Impact on Agriculture. Overview. The industrial revolutions have brought significant changes to the agricultural sector, transforming it into a highly efficient and productive industry..

First Industrial Revolution in Agriculture. 1. Challenges.

Second Industrial Revolution in Agriculture. 1. Challenges.

Third Industrial Revolution in Agriculture. 1. Challenges.

Fourth Industrial Revolution in Agriculture. 1. Precision Agriculture.

Conclusion. The evolution of agriculture through the industrial revolutions showcases the resilience, adaptability, and innovation of the industry. From mechanization to precision farming, agriculture has transformed into a highly data-driven and efficient sector, meeting the challenges of rapid population growth and climate change..

ADS- AIR. Chapter 2 Automated Drones: Bridging Physical and Digital Realms.

Introduction. Good morning, everyone. Today, we delve into the intersection of technology and physical systems, a space where the evolution of Cyber-Physical Systems (CPS) meets the innovative world of automated drones..

CPS Overview. At the forefront of the fourth industrial revolution, Cyber-Physical Systems (CPS) emerge as a groundbreaking concept. These systems seamlessly integrate physical and computational components, enabling the monitoring and control of physical processes. In essence, CPS represents the marriage of the digital and physical worlds, creating opportunities for unprecedented technological advancements..

CPS Features. CPS combines sensing, actuation, computation, and communication capabilities, enhancing the overall performance, safety, and dependability of physical systems. Key features include network communication, real-time computation, flexibility and adaptability, and robust security and privacy measures..

Applications of CPS. CPS finds applications across various sectors such as agriculture, aeronautics, and transportation. In agriculture, CPS enables automated monitoring, harvesting, and farming with drones and tractors, optimizing soil conditions and improving overall efficiency..

Introduction to Drones. Now, let's shift our focus to drones. Drones, also known as Unmanned Aerial Vehicles (UAVs), are aircraft operated without human pilots. They play a crucial role in various tasks, from delivery and surveying to photography and filming..

Components of Drones. Drones consist of several components, each playing a vital role. The frame provides structural support, batteries power the drone, propellers enable lift, and motors propel the drone. The flight controller processes data for stable flight, while sensors, including GPS, gyroscopes, and accelerometers, provide essential information..

Datalink and GCS. The datalink serves as the wireless connection between the drone and the Ground Control Station (GCS), allowing control and data signal transmission. The GCS, in turn, facilitates human control and monitoring of the drone during missions..

Drone System Workflow. Let's explore the workflow of a drone system. Starting from calibration, the flight controller processes control inputs and sensor data to ensure stable flight. Through the datalink, the drone communicates with the GCS, providing real-time updates and receiving commands. Drones may execute various tasks, from taking pictures to delivering payloads, depending on the application..

CPS and Drones Integration. The integration of CPS and drones creates a powerful synergy. CPS enhances the autonomous capabilities of drones, allowing for real-time decision-making, data collection, and remote exploration. This integration has transformative implications for industries ranging from agriculture to aeronautics..

Conclusion. In conclusion, the integration of CPS and drone technology represents a paradigm shift in how we interact with the physical world. From automated agriculture to advanced aeronautics, this synergy offers unparalleled possibilities. However, as with any technology, it's vital to balance innovation with environmental awareness and responsible usage..