EDN has announced the winners of the annual Electronic Products Product of the Year Awards in the January/February digital magazine. Now in its 50th year, EDN editors looked at over 100 products across 13 component categories to select the best new components. These categories include analog/mixed-signal ICs, development kits, digital ICs, electromechanical devices, interconnects, IoT platforms, modules, optoelectronics, passives, power, RF/microwave, sensors, and test and measurement.

These award-winning products demonstrate a significant advancement in a technology or its application, an exceptionally innovative design, a substantial achievement in price/performance, improvements in design performance, and/or the potential for new product designs and opportunities. This year, the awards have two ties, in the categories of power and sensors.

Also in the January/February issue, we look at some of the most advanced electronic components launched at the Consumer Electronics Show (CES). This year’s show highlighted the rise of AI across applications from automotive to smart glasses. Chipmakers are placing big bets on edge AI as a key growth area along with robotics, IoT, and automotive.

A few new AI chip advances announced at CES include Ambarella Inc.’s CV7 edge AI vision system-on-chip, optimized for a wide range of AI perception applications, and Ambiq Micro’s industry-first ultra-low-power neural processing unit built on its Subthreshold Power Optimized Technology platform and designed for real-time, always-on AI at the edge.

Though chiplets hold big promises in delivering more compute capacity and I/O bandwidth, design complexity has been a challenge. Cadence Design Systems Inc. and its IP partners may have made this a bit easier with pre-validated chiplets, targeting physical AI, data center, and high-performance-computing applications. At CES, Cadence announced a partner ecosystem to deliver pre-validated chiplet solutions, based on the Cadence physical AI chiplet platform. The new chiplet spec-to-packaged parts ecosystem is designed to reduce engineering complexity and accelerate time to market for developing chiplets while reducing risk.

We also spotlight the top 10 edge AI chips with an updated ranking, curated by AspenCore’s resident AI expert, EE Times senior reporter Sally Ward-Foxton. As highlighted by several CES product launches, more and more AI chips are being designed for every application niche as edge devices become AI-enabled. These devices range from handling multimodal large language models in edge devices to those designed for vision processing and minimizing power consumption for always-on applications.

Giordana Francesca Brescia, contributing writer for Embedded.com, looks at microcontrollers with on-chip AI and how they are transforming embedded hardware into intelligent nodes capable of analyzing and generating information. In addition to hardware innovations, she also covers software development and key areas of application such as biomedical and industrial automation.

We also spotlight several emerging trends in 2026, from 800-VDC power architectures in AI factories and battery energy storage systems (BESSes) to advances in autonomous farming and power devices for satellites.

The wide adoption of AI models has led to a redesign of data center infrastructure, according to contributing writer Stefano Lovati. Traditional data centers are being replaced with AI factories to meet the computational capacity and power requirements needed by today’s machine-learning and generative AI workloads.

However, a single AI factory can integrate several thousand GPUs, reaching power consumption levels in the megawatt range, Lovati said. This has led to the design of an 800-VDC power architecture, which is designed to support the multi-megawatt power demand required by the compute racks of next-generation AI factories.

Lovati also discusses how wide-bandgap semiconductors such as silicon carbide and gallium nitride can deliver performance and efficiency benefits when implementing an 800-VDC architecture.

The adoption of BESSes is primarily being driven by the need to improve efficiency and stability in power distribution networks. BESSes can balance supply and demand by storing energy from both renewable sources and the conventional power grid, Lovati said. This helps stabilize power grids and optimize power uses.

Lovati covers emerging trends in BESSes, including advances in battery technologies, hybrid energy storage systems—integrating batteries with alternative energy storage technologies such as supercapacitors or flywheels—and AI-based solutions for optimization. Some of the alternatives to lithium-ion discussed include flow batteries and sodium-ion and aluminum-ion batteries.

We also look at the challenges of selecting the right power supply components for satellites. Not only do they need to be rugged and small, but they must also be configurable for customization.

The configurability of power supplies is an important factor for meeting a variety of space mission specifications, according to Amit Gole, marketing product manager for the high-reliability and RF business unit at Microchip Technology.

Voltage levels in the electrical power bus are generally standardized to certain values; however, the voltage of the solar array is not always standardized, Gole said, which calls for a redesign of all of the converters in the power subsystems, depending on the nature of the mission.

Because this redesign can result in cost and development time increases, it is important to provide DC/DC converters and low-dropout regulators across the power architecture that have standard specifications while providing the flexibility for customization depending on the system and load voltages, he said.

Gole said functions such as paralleling, synchronization, and series connection are of key importance for power supplies when considering the specifications of different space missions.

We also look at the latest advances in smart farming. With technological innovations required to improve the agricultural industry and to meet the growing global food demands, smart farming has emerged to support farming operations thanks to the latest advancements in robotics, sensor technology, and communication technology, according to Liam Critchley, contributing writer for EE Times.

One of the key trends in smart farming is the use of drones, which help optimize a variety of farming operations. These include monitoring the health of the crops and soil and communicating updates to the farmer and active operations such as planting seeds and field-spraying operations. Drones leverage technologies such as advanced sensors, communication, IoT technologies and, in some cases, AI.

Critchley said one of the biggest developing areas is the integration of AI and machine learning. While some drones have these features, many smart drones will soon use AI to identify various pests and diseases autonomously, eliminating the need for human intervention.

Cover image: Adobe Stock

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