ROHITH S’ Post

🚀 I recently had the opportunity to participate in Ford's job simulation on the Forage platform, and it was an incredible learning experience! 🌟 I worked on a project where I collected data from an analog sensor using an ESP32, gaining hands-on experience with both analog and digital systems. This real-world context really helped solidify my understanding of embedded systems and microcontroller projects. Through this program, I realized how much I enjoy working on these types of projects, and I'm excited to apply these skills in future embedded systems roles. 💡 #EmbeddedSystems #Microcontrollers #ESP32 #Ford #JobSimulation #Forage #AnalogSystems #DigitalSystems #Learning #Engineering #TechInnovation #CareerDevelopment

Automotive embedded systems

🌟 Microcontroller 8051-Based Obstacle Avoider Robot 🌟 I’m thrilled to share my recent project: successfully designing and developing an 8051 Microcontroller-Based Obstacle Avoider Robot! This endeavor highlighted my passion for embedded systems and robotics while refining my technical expertise in these fields. 🔍 Key Features: Sensor Integration: IR sensors placed strategically on the front, left, and right to detect obstacles in real time. Signal Processing: Utilized an operational amplifier (op-amp) to convert analog sensor signals into digital inputs for the microcontroller. Autonomous Navigation: The 8051 microcontroller processes input signals, determines the optimal navigation path, and seamlessly controls motors via a driver circuit for smooth and efficient movement. ⚙️ Project Highlights: This project encompassed the complete development lifecycle: Circuit Design & Component Integration: Ensuring robust and efficient hardware functionality. Firmware Programming: Writing real-time decision-making algorithms for autonomous navigation. Hardware Assembly: Integrating sensors, microcontroller, and motor drivers into a cohesive system. 🚀 Outcomes: Gained hands-on experience in microcontroller programming, sensor interfacing, and motor control. Enhanced problem-solving and debugging skills. Strengthened my understanding of circuit design principles and real-time embedded systems. This project was a fantastic learning experience and a step forward in my journey of building intelligent and autonomous systems. I’m excited to explore more innovations in this field! #EmbeddedSystems #Robotics #Microcontroller #ProblemSolving #Innovation

EV Powertrain and Embedded Systems (EVPES) course! 🌟 🌟 Excited to announce the successful completion of my EV Powertrain and Embedded Systems (EVPES) course! 🌟 After 400 hours of intense training from Autobot Academy, I’m now certified with in-depth expertise in electric vehicle powertrain technology, embedded systems, and sustainable transportation solutions. This journey has equipped me with critical skills in EV battery technology, powertrain modeling, motor control, and embedded systems—key components in designing the future of mobility. Highlights of My Learning: EV Architecture and Powertrain Selection Process: Comprehensive understanding of power and communication architectures for EVs. Battery Technology and Modeling: Skills in battery soft pack design using CAD software, and performing Li-ion cell testing at different charge and discharge rates. Embedded Systems Integration: Experience with sensors, microcontrollers, and various communication protocols for EV applications. Hands-On Experience: 🔹 Designed and simulated MATLAB models for EV powertrain, battery pack, and motor control. 🔹 Created detailed battery pack configurations in SolidWorks, including cell design and parallel/series configurations. 🔹 Worked on EV powertrain integration, motor-controller-throttle setups, and conducted charging/discharging performance tests. This certification has enhanced my abilities in project management, problem-solving, and technical innovation, empowering me to contribute effectively to the EV industry. I’m looking forward to leveraging these skills in real-world projects and advancing the future of electric mobility! ⚡ #ElectricVehicle #EVPowertrain #EmbeddedSystems #AutobotAcademy #MATLAB #SolidWorks #SustainableMobility #BatteryTechnology #CareerGrowth #ElectricMobility

eVTOL Design Challenges: Solutions to Safe & Efficient Embedded Software Design Register FREE - Nov 14 | Session 1 9AM (CET) | Session 2 11AM (EST) 👉https://ansys.me/3CfaMyc #ANSYS partners with SYSGO - Embedding Innovations to showcase fast, efficient and safe solutions for embedded software for eVTOL applications. Embedded software plays a crucial role in coordinating all these technological advances. From pure actuator control to sensor data fusion and high-level mission planning, software coordinates the effectiveness and safety of the aircraft. What You Will Learn: ✅Understand the new challenges behind #eVTOL design ✅Discover the solutions that SYSGO and Ansys combine to design embedded software ✅Demo to run a simulated eVTOL transport mission Who Should Attend? Embedded developers / embedded R&D team managers in the Advanced Air Mobility sector, Software Engineers, Software Developer, Control Engineers, System Engineers. #embeddedsoftware #SCADE #AdvancedAirMobility

🚗💡 Excited to share that I’ve completed my Master’s program in Electric Vehicle Design. This journey has equipped me with cutting-edge skills in MATLAB, Simulink, and other industry-standard tools, with a focus on Embedded Systems, EV Architecture, Motor Controller, Battery Management System, Power Electronics, EV Motors. Throughout the program, I had the opportunity to work on industry-based projects, tackling real-world challenges in EV technology and systems integration. These hands-on experiences have deepened my understanding of vehicle electrification, control systems, and power management. Looking forward to applying my knowledge and contributing to the future of sustainable mobility! 🌱🔋 #ElectricVehicles #EVDesign #EmbeddedSystems #Matlab #Simulink #ModelBasedDevelopment #SustainableMobility #GreatLearning

🚀 dSPACE Hardware-in-the-Loop (HiL) Testing Simplified 🌟 HiL testing is a game-changer for validating and verifying embedded systems. With dSPACE, you can simulate real-world scenarios and test control systems without the risk of damaging actual hardware. 💡 From creating plant models in MATLAB Simulink to real-time execution on dSPACE hardware, the process ensures accuracy and efficiency. ControlDesk becomes your ultimate companion for real-time monitoring, parameter tuning, and fault injection. 🔧 Whether you're testing powertrains, ADAS systems, or battery management, dSPACE provides unmatched precision and scalability. Plus, automation tools like AutomationDesk streamline complex test cases for faster results. 🚘 Say goodbye to late-stage bugs and hello to early detection, cost savings, and reliable systems! 🖥️✨ #HiLTesting #dSPACE #AutomotiveEngineering #MATLAB #EmbeddedSystems #RealTimeSimulation #Innovation #TechPost #Electronics #EEE #Electrical #Engineers #ChetanShidling #CSElectricalAndElectronics #Coding

Welcome to #Day 9 of #30daysofESP32Programming with DeeThunder! ⭐ Today, we’re exploring the fascinating world of servo motors. These motors are essential for projects requiring precise control of angular position, such as robotics, automation, and more. We’ll also touch on the importance of snubber circuits when working with servos and LCDs to ensure smooth and reliable operation. Servo motors are widely used in various applications due to their ability to provide precise control over angular position. They typically rotate between 0° and 180° and are controlled using Pulse Width Modulation (PWM) signals. Types of Servo Motors Positional Rotation Servo: Rotates between 0° and 180°. Continuous Rotation Servo: Rotates continuously in either direction. Linear Servo: Moves in a straight line instead of rotating. Snubber Circuits Snubber circuits are used to protect electronic components from voltage spikes and transients. They typically consist of resistors and capacitors and are crucial when working with inductive loads like motors. In the context of servo motors, snubber circuits help to: 1. Reduce electromagnetic interference (EMI) 2. Protect the motor driver and other components 3. Improve the longevity and reliability of the system Interfacing a Servo Motor with ESP32 ESP32 board Servo motor Breadboard and jumper wires Snubber circuit components (resistor and capacitor) Wiring Diagram GND: Connect to the GND pin on the ESP32. VCC: Connect to the 5V pin on the ESP32. Signal: Connect to GPIO 26 on the ESP32 Using Snubber Circuits with Servo Motors When working with servo motors and LCDs, it’s essential to use snubber circuits to protect against voltage spikes. A simple RC snubber circuit can be connected across the motor terminals to dampen oscillations and protect the components. Applications Robotics: For precise movement and control Automation systems: For controlling valves, levers, and other mechanisms Aerospace: For controlling flight surfaces and other critical components I’m Atanda Isaac-great, a Graphics & UI designer, Electrical Engineering student, embedded system engineer, and IT support engineer. I help provide solutions and aim to provide opportunities for growth. Click on the link to connect: https://lnkd.in/dMFAuCNq #embeddedsystems #electronicsengineering #microcontrollers #espboards #esp32interfacing #servomotors

🚗 Excited to have attended the Automotive Embedded Systems Workshop today! 🌟 I had the opportunity to dive deep into the latest advancements in automotive technology, exploring how embedded systems are revolutionizing vehicle performance and safety. From real-time operating systems to cutting-edge software development And Testing techniques, the workshop provided invaluable insights into the future of automotive engineering. #AutomotiveEngineering #EmbeddedSystems #Innovation #TechWorkshop #ContinuousLearning