GITAI’s Post

Does anyone ever wonder, how many STEM careers fall within a single sector such as Aviation? Here's a few to kick it off, but this only scratches the surface.. Aerospace Engineer Aircraft Maintenance Engineer Avionics Technician Air Traffic Controller Aircraft Systems Engineer Flight Test Engineer Aerospace Software Engineer Aerospace Materials Engineer Aerospace Data Analyst Aerospace Research Scientist Aerospace Project Manager Aerospace Quality Assurance Engineer Aerospace Technical Writer Aerospace Propulsion Engineer Aerospace Structural Engineer Aerospace Electrical Engineer Aerospace Manufacturing Engineer Aerospace Operations Research Analyst Aerospace Safety Engineer Aerospace Robotics Engineer And the growth areas? Sustainable Aviation: With increasing environmental concerns, there's a growing focus on developing eco-friendly aviation technologies, such as electric and hybrid aircraft propulsion systems, biofuels, and lightweight materials to improve fuel efficiency and reduce emissions. Unmanned Aerial Systems (UAS): The use of drones for various applications, including surveillance, mapping, delivery services, and agriculture, is expanding rapidly. This creates opportunities for S.T.E.M. professionals in drone design, operations, maintenance, and data analysis. Urban Air Mobility (UAM): The concept of flying taxis and autonomous air vehicles for urban transportation is gaining traction. This requires expertise in electric propulsion, autonomous systems, air traffic management, and infrastructure development. Digitalization and Data Analytics: Aviation companies are increasingly leveraging data analytics, artificial intelligence, and machine learning to optimize operations, enhance safety, and improve passenger experience. Careers in data science, cybersecurity, and software development are in high demand. Advanced Materials and Manufacturing: Innovations in materials science, such as composites, alloys, and additive manufacturing, are driving advancements in aircraft design, performance, and durability. S.T.E.M. professionals are needed to develop and implement these technologies. Space Exploration: The commercial space industry is experiencing rapid growth, with companies like SpaceX, Blue Origin, and Virgin Galactic leading the way. Opportunities exist in space tourism, satellite deployment, lunar exploration, and beyond-Earth missions, requiring expertise in engineering, physics, and robotics. Air Traffic Management (ATM) Modernization: Upgrading air traffic control systems with NextGen technologies, satellite-based navigation, and automation improves airspace capacity, efficiency, and safety. This field offers careers in systems engineering, software development, and human factors. #STEMinAviation #AviationCareers #Teamstar #ThinkCreateCollaborate #ExploringSTEMCareers

🚨🚨 Time’s running out… Charge Robotics (YC S21) is hiring SWEs to build solar construction robots🚨🚨 They say short lists are made within the first week. Act quickly to make the cut!! Charge Robotics (YC S21) is hiring SWEs to build solar construction robots https://ift.tt/aEJsNzu If you need a hand in getting prepared, I offer #resume services and #interview prep support. Click the link to book a slot on my Calendly before it fills up! https://ift.tt/mlt56az *Note: I am not hiring or sourcing for this role. If you are interested in applying, please do so through the link in the post.

I shouldn��t have my job. ❌ Growing up, New Zealand had no space jobs. ❌ I had no space industry experience. ❌ I knew nothing about rockets or spacecraft. ❌ What did I have to offer the space industry? The same is true for many of the people who have made Rocket Lab what it is today. But we took the huge variety of skills we all developed across industries and put them into solving space problems in new ways. The result is a world leading space company. The team behind Electron production is hiring right now. Many of the people building rockets today used to build cars, planes, boats, and medical devices. Or they were mechanics, sparkies, machinists and much more. They took those skills and applied them to rockets with exceptional results. We can’t teach grit. Determination. Relentless drive. Innovation. You have to bring those. But rocket science? We can teach that.

Many Robotics/CV roles require candidates to have an understanding of camera calibration, bundle adjustment, and proficiency in C++ skills. I explain these topics and perform BA on the BAL dataset (https://lnkd.in/g_HJGC-r) using the C++ Ceres library. The BAL dataset utilizes images from Flickr to create a point cloud of buildings in various locations such as Rome, Venice, Denmark, etc. Below, I present the output of my bundle adjustment performance on this dataset. This repository can serve as a valuable resource for individuals interested in similar job profiles requiring expertise in these areas. git repo: https://lnkd.in/gVqFi26F checkout my portfolio : https://lnkd.in/graPtWST

Explore how MATLAB based interactive tools help you to accelerate conceptual design phase of your aerospace vehicle with an objective to maximize competition score. https://lnkd.in/dp93c2ez

How to code like 🚀 NASA? NASA faces the following challenge: Once you "launch" your rocket, you cannot change your code. THEREFORE, They have created the NASA 10 coding principles. For maximum code reliability. My favorite is: "NASA recommends that functions should be up to 60 lines. This means that they can fit on a single A4 page." May your code be always bug-free! Have fun 🙂 ... P.S. Looking for a remote developer job? 👉 Sign up on RemoteMore . #coding #standards #developers

Did you know that space travel and playing football on the Moon wouldn’t even be possible without the help of engineers and technologists who help make it all happen? Well on the Institution of Engineering and Technology (IET)'s website you can now discover more about the exciting and varied engineering and technology careers and roles that could prove vital for work on the Moon in the future. At ROSEN, I specialise in ensuring our software complies with various internal and international quality standards and regulations. I look at not just our code, but also our processes, culture and team to see where quality can be improved to ensure we deliver reliable products. Essentially this means I’m good at looking at the rules and seeing how well we abide by them. This is great when trying to come up with the rules for lunar football and seeing how the earth rules need to be amended to work in the ecosystem of the moon. Software is going to play a key role in the future of space exploration. We will need scripts to help regulate oxygen levels, send communications back to Earth, determine launch trajectories for space craft - and that’s just the tip of the iceberg. Space is also potentially the harshest of all known environments, so we will need to build software that astronauts can trust to keep them safe, which is where the world of safety critical software comes into its own. Find out more about my work and check out the career profiles of other amazing engineers: https://buff.ly/3YbuJN8 #WomenInTech #WomenInSTEM #MoonUnited #WomenInEngineering #Tech #STEM #Engineering #RoleModel #SoftwareEngineering #Space

“The massive difference between Project Kuiper and other aerospace companies is the ability to develop at scale within months vs. years or decades. Normally within an aerospace career you are lucky to see one or two of your projects in space. With Project Kuiper, there is an opportunity to see thousands.” - Britta, Satellite Integration and Test Engineer Britta conducts comprehensive satellite-level testing which includes evaluating the entire system’s capabilities and assessing performance across various environments from simulating vibrations and acoustics during launch to subjecting the satellite to thermal and vacuum conditions it will encounter in space. Britta and her team ensure that the satellite operates optimally and withstands the demanding conditions it will face throughout its mission. “This is a really interesting time as an engineer. It’s a time of innovation where not all the rules are set in stone. Instead, we have the unique opportunity to actively be part of crafting and establishing those very rules. It’s empowering to be at the forefront of shaping new frontiers and driving progress in your field.” Learn more about Project Kuiper and explore open roles: https://amzn.to/3D6e1Fn #InsideAmazon #ProjectKuiper #HereAtAmazonDevices

Have you seen the movie October Sky? Do you also admire the sheer beauty a rocket launch has, hearing the shock waves of the supersonic jet through the nozzle? Do you know that you can make a rocket with a lot of sugar? Are you also interested to know step-by-step on how exactly a propulsion system can be designed for a high power rocket, connecting all the dots? Do you see a lot of hobby-rocketry software out there but have no clue what's happening under the hood? All the above quests are humbly attempted in this work that I propose here. But before everything, I would like to share my gratitude to my internship mentors and the co-authors of this work: Dr. Anilkumar Markana Sir and Dr. Parth S. Thakar bhai for their constant guidance and support. Without their careful observations on the intricate details, this work might not have achieved such standards of veracity. At this stage, I also cannot forget mentioning about the my mentor/friend, the Director of Research of my bachelors university, Dr. K Nandakumar Sir (in-office during my batch 2018-22) for firing my quest in rocketry and to teach me patience with it. Not to look at the rockets as a kid but an engineer. So, coming back, this work mainly focuses on what all parameters and state-variables one should look at while designing a high power rocket. It shows an amateur in rocketry what comes first and what follows when. It would take you to the world of solid rocket propulsion using the fundamentals and designing one with rocket candy as an example. It's all rocket science there, go have a look! And do let me know if you have any comments on it. Cheers! Sincerely, Soham Rajesh Prajapati

Unlocking Drone Potential: Payload & Python Scripting 🚀💼 Payload capacity is a pivotal factor in drone design, shaping their versatility and real-world applications. But with cutting-edge flight controllers and motors, we're on the cusp of a transformative shift. 🌐 Traditionally, limited payloads confined drones to specific roles. Now, advanced flight controllers wield precision and stability even under hefty loads. 🎮💼 🔄 Innovative motors offer higher thrust-to-weight ratios, enabling drones to tackle diverse industries with ease. 📸🌾🆘 As payload boundaries expand, drones redefine how we work and interact with the world. But there's more: Python scripting via Dronekit empowers us further. 🐍💻 Python's magic in drone ops: 1. 📐🛣️ Optimized Flight Paths reduce energy consumption. 2. 💾📡 Data Compression saves precious payload capacity. 3. ⚖️📦 Load Balancing ensures mid-air stability. 4. 📊🔍 Real-time Monitoring enhances safety and efficiency. 5. 🎛️📹 Remote Payload Control conserves energy for critical tasks. Here is a video of my latest autonomous drone running payload optimizing parameters and script on Dronekit. The commands are transmitted in real time through wireless telemetry radios. The height limit and thrust of the drone motors are self-calculated according to the payload attached (currently its body) with a safety factor of 5. With Python scripting, we adapt to and minimize payload constraints, maximizing drone potential. 🚀💼 #DroneTech #PythonScripting #PayloadConstraints