Analog Design & Layout
Armstrong Technologies
Semiconductor
At the intersection of innovation and precision, our expertise in analog semiconductor design enables us to craft custom analog circuits and layouts tailored to your specific needs. Our skilled engineering team blends creativity with deep technical knowledge to develop high-performance, reliable analog solutions that meet the most demanding application requirements.
Key Features
Circuit Design
​We recognize that each application comes with its own set of requirements, which is why we emphasize delivering fully customized circuit design solutions. Our process begins with a deep understanding of your specific needs, enabling us to craft designs that align precisely with your performance goals. Whether your focus is on ultra-low noise, high linearity, or wide bandwidth, our team collaborates closely with you to create circuits that effectively address your unique challenges and deliver optimal results.
Analog / RF Layout
Each analog and RF circuit presents its own design challenges, which is why our custom layout solutions are precisely tailored to your specific requirements. From low-noise amplifiers and high-frequency oscillators to intricate RF front-end modules, we collaborate closely with your team to create optimized layouts that enhance performance while ensuring compliance with design specifications and manufacturing guidelines.
AMS Simulation & Automation
Our AMS simulation expertise spans a comprehensive set of tools and methodologies designed to verify the functionality and performance of analog and mixed-signal circuits. Whether performing detailed transistor-level analysis or high-level behavioral modeling, we utilize state-of-the-art simulation platforms to reliably predict circuit behavior across a wide range of operating conditions.
Analog Behavioural Modelling
Analog Behavioral Modeling provides a high-level approach to accurately represent complex analog circuits. Whether working on amplifiers, filters, or data converters, our modeling techniques focus on capturing the core functional behavior without relying on detailed transistor-level schematics. This approach accelerates design exploration, enabling quicker iterations and faster convergence toward optimal design solutions.
