Designing Analog and Mixed-Signal (AMS) integrated circuits has always demanded deep expertise, long iteration cycles and precision tuning across layout, performance and electrical behavior. Unlike digital ICs, AMS designs do not scale easily with abstraction or automation due to their sensitivity to physical design and interaction with real-world signals. Erik Hosler, an advocate for design-intelligent systems, recognizes that AI co-design tools are now reshaping this domain, accelerating what was once a painstakingly manual craft into a more efficient and intelligent process.
The integration of AI into co-design environments offers simultaneous optimization across schematic intent, layout constraints and performance targets. By learning from historical designs and real-time simulation feedback, AI models help reduce guesswork, compress iteration loops and support engineers in developing high-performance analog blocks with greater speed and confidence.
The Intricacies of Analog and Mixed-Signal IC Design
AMS IC design demands a delicate balance between performance, power, area and noise. Unlike digital flows, where logic gates and standard cells can be arranged with predictable behavior, analog circuits depend heavily on device sizing, matching, parasitics and routing symmetry. Every change in layout can influence circuit performance, requiring back-and-forth tuning that may span weeks.
AMS blocks must also interact seamlessly with digital systems, which adds complexity to interface timing, signal integrity and mixed-domain simulation. Achieving design closure across these domains requires extensive collaboration and verification effort, often placing a bottleneck on broader System-on-Chip (SoC) schedules.
Why Traditional AMS Flows Resist Automation
The analog design process has traditionally been resistant to automation due to its reliance on human intuition and analog art. Layout engineers use techniques honed over the years to handcraft structures for optimal matching, shielding and current flow. Much of this tacit knowledge is difficult to capture in rules or scripts.
Even existing analog automation tools often fall short because they cannot reason across domains. A layout optimization tool may suggest a routing strategy that reduces area but introduces parasitic capacitance that degrades performance. Without cross-domain awareness, such tools may create more rework than relief.
Introducing AI Co-Design: Simultaneous Optimization from Schematic to Layout
AI-powered co-design tools are changing this landscape by treating schematic design and layout as interconnected problems rather than separate steps. These tools use machine learning to understand how circuit performance is affected by layout features, enabling them to suggest topologies and physical implementations that meet design goals concurrently.
Suppose an engineer sets a constraint on gain, noise and layout symmetry. In that case, the AI model can explore circuit variants and layout strategies that balance these parameters within given silicon area limits. Instead of generating one layout per schematic, the model iteratively proposes and refines both domains in tandem, streamlining the path to closure.This co-design approach enables engineers to focus on architectural intent while letting AI handle optimization and verification at the micro level.
Reinforcement Learning for Layout-Aware Circuit Design
One of the most promising techniques in AI co-design is reinforcement learning, where the model learns optimal layout and schematic strategies through trial and reward. Each layout it generates is evaluated using simulation feedback, and the model updates its policies based on what produces better performance and fewer design rule violations.
This method enables the exploration of creative or non-obvious solutions that human designers might overlook. It also speeds up convergence on complex blocks like analog-to-digital converters, voltage regulators or phase-locked loops, where multiple design goals compete with tight constraints.By treating each placement, routing and sizing decision as part of a continuous learning process, reinforcement-based AI transforms layout from a handoff into an active design dimension.
Capturing Designer Intent and Guiding Topology Exploration
Another breakthrough in AI co-design is its ability to interpret and preserve designer intent. Rather than overriding human judgment, these tools augment it by learning from labeled design data, annotated schematics and performance specs.
If a designer marks a differential pair as needing strict matching and shielding, the AI respects this constraint throughout its optimization passes. This intent-aware behavior ensures that generated layouts are not only electrically correct but also aligned with the design philosophy.
At the same time, AI models assist in topology exploration by analyzing prior circuit architectures and identifying high-performing configurations. They can generate variations that inherit desirable traits while adapting to new specs or process nodes, saving hours of early design exploration.
From Bottleneck to Accelerator: Reducing Verification Burden With AI
Verification is often the longest and most resource-intensive phase of AMS IC development. Each design change requires fresh simulation, Layout Versus Schematic (LVS) checks and parasitic extraction. AI co-design tools reduce this burden by minimizing disruptive changes and flagging issues earlier in the flow.
Some models are now capable of predicting whether a layout will pass verification checks based on its structure and metrics. Others estimate performance shifts due to layout changes before simulation, enabling preemptive correction. These predictive capabilities help engineers avoid unnecessary rework and reduce the number of post-layout surprises.
These AI-powered tools are helping engineers overcome the limits traditionally imposed by manual analog flows. By enabling layout-aware circuit generation and continuous learning from simulation data, AI is allowing teams to extract more value from legacy process nodes and established architectures. Erik Hosler observes, “Modern society is built on CMOS technology, but as we push the boundaries of what these devices can do, we must innovate within the CMOS framework to continue driving performance, efficiency, and integration.” This reflects the essence of AI co-design in analog and mixed-signal workflows. It empowers engineers to innovate without abandoning the proven foundations of CMOS design, accelerating progress while maintaining design trust and integrity.
A Shift Toward Collaborative and Scalable Analog Design
Beyond individual efficiency gains, AI co-design tools also foster a more collaborative development model. Because these platforms record decisions, rank outcomes and document trade-offs, teams can work more transparently across geographic and functional boundaries.
This documentation and insight-sharing make it easier to onboard new designers and scale analog IP development across multiple projects. Instead of reinventing circuits from scratch, teams can reuse AI-curated libraries and adapt them to new use cases with minimal tuning.This shift reduces dependency on a small pool of expert analog designers and opens the door to scalable analog innovation that aligns with the speed of digital SoC development.
Accelerating Analog Innovation Through Co-Design
As the demand for power-efficient, high-performance analog and mixed-signal functionality continues to grow, AI co-design tools are poised to play a transformative role. By unifying schematic intent, layout precision and performance constraints into a single intelligent workflow, these tools help engineers work faster and smarter. They reduce trial-and-error cycles that often slow down analog development and provide designers with real-time guidance throughout the process. This leads to better first-pass results and fewer late-stage surprises.
The result is not just a faster time to tape out but a more robust, scalable and efficient analog IP that supports modern system requirements. AI co-design brings a new level of confidence to AMS development, one rooted in data, feedback and continuous learning.With AI as a co-pilot, the path from concept to silicon becomes more transparent and repeatable, empowering teams to push the boundaries of what’s possible in analog design.