Devices are becoming smarter, more capable, and more distributed, but the way we design them has not kept pace. For engineers, that progress increasingly brings tradeoffs: latency bottlenecks, rising power demands, and fragmented system architectures that complicate even well-understood designs. As functionality increases, so does the difficulty of fitting multiple analog and digital components onto a single board, while meeting strict size, weight, and power requirements.
The goal isn’t just integration. It’s better outcomes. Integrating processing and connectivity helps reduce system complexity, improve reliability, strengthen security, and simplify the development experience for design teams. It accelerates time to market and supports AI-capable products across applications ranging from consumer devices to industrial and physical AI systems.
Advances in mixed-signal design are making this level of integration practical at scale. By integrating a wireless chip and a microcontroller, engineers can eliminate chip-to-chip interconnect complexity, thereby simplifying board layouts, improving power management, and making system integration faster and more efficient.
The Happy Marriage of Connectivity and Compute
Bringing together connectivity and processing changes how design decisions are made early in the product lifecycle. When core system functions work together, teams can simplify architecture choices from the outset and reduce the number of variables that typically slow progress.
Traditionally, developers have had to account for board layout while coordinating both hardware and software development across separate components and teams. That level of coordination increases design complexity, introduces roadblocks, and can slow development and time to market. An integrated solution removes much of that friction.
Long-Term Benefits and Efficiencies of Integration
Integrating connectivity and compute has benefits beyond the engineering and manufacturing phase. Over the lifetime of a product, integration helps reduce power consumption, lower device weight, and decrease overall system cost. At scale, even small reductions in size, mass, and power can translate into meaningful savings across production, shipping, and years of deployment.
These efficiencies matter across a wide range of IoT applications, including smart appliances, home and industrial automation, and home security. For products that must meet stringent energy requirements, integration can make it significantly easier to achieve electricity consumption targets.
Reliable wireless performance over longer distances is another critical factor. Connectivity can be power- and workload-aware. Products such as washers, dryers, and thermostats are often installed far from a router, where inconsistent connectivity can undermine the overall experience. More efficient system designs enable robust and reliable wireless connections in these real-world environments.
Bring Processing and Connectivity Together with Synaptics
As leaders in connectivity, Synaptics focuses on helping engineers improve designs through high-performance wireless solutions that deliver strong rate, range, and reliability. That expertise drives our approach to integrated platforms, where connectivity and processing are designed to work together from the start.
As Wi-Fi 7 brings higher speeds and lower latency to the IoT, Synaptics connectivity solutions are built to help engineers take advantage of these capabilities while simplifying system design and improving overall connectivity.