The main emphasis of research on integrated software and hardware systems has been on design and development methods. The study's goal was to create a single framework. One of the key aims of the project was to figure out how to plan development work while keeping in mind the restrictions of hardware and software. This was very important since there has been a clear rise in the number of initiatives that are seeking to connect a system's digital logic to its physical parts. A close look into co-design methods showed that working together early on between the software and hardware teams had a big effect on the system's efficiency, scalability, performance, and performance. The goal of this assessment was to show how big of an effect this partnership had. This research looks at various successful methods that can make it possible to build things in parallel while also lowering the risks of integration. These include iterative prototyping, hardware/software co-simulation, and model-based design. Since they were possible and somewhat effective, they were the ways that were being looked at. Researchers looked at development tools and platforms like as hardware description languages (HDLs), real-time operating systems (RTOS), and FPGA prototype environments to see whether they might speed up development and make system validation easier. Researchers discovered that these platforms and technologies made development a lot easier. Embedded systems, automotive control units, and Internet of Things apps were looked at as real-world examples to show how integrated development methods may be useful in real life. The point of doing this was to show how development plans may be beneficial.