RACSEMI is proud to provide tailored cyber security solutions and advisory services across a diverse range of market segments. Our expertise and commitment to impartiality enable us to deliver strategic insights and effective security measures for organisations of all sizes and complexities. Our key market segments include:
A Proof of Concept (PoC) using an FPGA enables rapid prototyping of semiconductor designs. FPGAs are reprogrammable chips ideal for testing logic, performance, and functionality before committing to ASIC production, reducing development risks and costs in advanced electronic systems.
The Fab Interface connects semiconductor design teams with fabrication facilities (fabs). It manages data exchange, design rule checks, mask generation, and production schedules, ensuring seamless transition from design to manufacturing. A robust fab interface is crucial for efficient, error-free chip fabrication and timely product delivery.
System design involves architecting and integrating hardware and software components to create complete electronic solutions. In semiconductors, it defines how chips interact within devices, covering processor selection, memory, interfaces, and power management. Effective system design ensures functionality, performance, and scalability in products like smartphones, vehicles, and IoT devices.
In semiconductors, IP (Intellectual Property) work involves designing, developing, and integrating reusable logic blocks or functional units, such as processors, memory controllers, or interfaces. These IP cores accelerate chip development, reduce costs, and ensure reliability. IP work is essential for creating efficient, scalable, and high-performance SoCs (Systems on Chip).
Physical design is the process of transforming a chip’s logical representation into a physical layout. It includes placement, routing, clock tree synthesis, and design rule checks. This stage ensures the chip can be manufactured efficiently while meeting performance, area, and power targets in ASIC and SoC development.
Post-silicon refers to validation, debugging, and performance tuning of semiconductor chips after fabrication. Engineers test real silicon to verify functionality, identify hardware issues, and fine-tune firmware or software. This critical phase ensures the chip meets specifications and is ready for mass production and deployment in real-world applications.
Software in semiconductors includes firmware, drivers, and system-level programs that enable hardware functionality. It controls chip operations, interfaces with operating systems, and optimizes performance. Software development is vital for unlocking hardware potential, enabling features, and ensuring seamless integration of semiconductor devices within electronic systems. Want me to tailor this for embedded systems, OS-level, or application software?
Advising insurers on data protection, compliance, and threat mitigation to enhance customer trust and regulatory adherence.