The Perfect Match – (U)WBG Semiconductors and Information Technology are Revolutionizing Power Electronics
All-electric Society
In power electronics, a fundamental change is happening. Two very dynamic sectors are currently automotive electronics and energy technology. In both application areas, there is a race for ever more efficient, high-performance and cost-effective power electronics systems. On top of this, there are increased requirements in terms of the reliability and service life of the electronic parts and components.
The main purpose of power electronics is the conversion and distribution of electrical energy using electronic switches between different sources, energy storages and loads that are electrically linked to each other. Power electronics fulfill these functions both in stationary applications, such as integrating renewable energy sources into the power grid, and more and more in mobile applications, like in battery electric vehicles. The central and crucial components here are the electrical converters, which can be used, for example, as chargers, voltage converters or drive inverters.
Faster – Stronger – Higher
With drive outputs of up to 1000 kW and ranges of over 1000 km, electric powertrains for electric cars have reached a new level. The electric converters are operating in the megawatt class. As a result, vehicle electronics are advancing vehemently into the area of larger drives and opening up further interesting fields of application. Outstanding examples are the emerging electrification in ships and aviation.
Hybridization, i.e., the combination of combustion engines or jet propulsion systems with fuel cell technology and battery storage, promises enormous savings in terms of fuel consumption and emissions. Alongside batteries, hydrogen is becoming an interesting energy carrier. The hydrogen technology in turn opens up its own technological possibilities, such as the design of cryogenic converters or the use of superconducting cables and motor windings. However, classic silicon components have reached their physical limits and the use of wide-bandgap semiconductors such as silicon carbide or gallium nitride is a necessity
Taking off with WBG
WBG-based power devices offer low on-state losses, enable higher switching frequencies and can handle high currents at high operating voltages. They provide superior thermal properties and are suitable for operation in a wide temperature range. Customized device and process technologies, such as VDMOS, pave the way to fully exploit the potential of WBG semiconductors for power electronics.
In terms of industrial application, SiC (silicon carbide) and GaN (gallium nitride) semiconductor technologies have gained significant impact on the market. However, there are still unlocked advantages at system level in terms of cost, efficiency, and construction volume. Current research activities are focused on an in-depth understanding of device characteristics and materials properties, not only on device level.
In the development of WBG-capable modules, especially GaN and SiC power modules, various technical challenges remain to be investigated. So, to realize highest efficiency power electronic conversion with fast switching, parasitic effects have to be minimized. In this context, the spatial and functional integration of the semiconductor switches with the driver control is crucial.
New challenges for WBG power modules come from extreme temperatures like cryogenic as well as high-temperature applications with appropriate adaptations to the packaging technology. Accordingly extended qualification measures and test procedures are required, that take novel failure mechanism into account. With special environmental and operational conditions, aviation is one of the hardest areas to conquer. Reliability is the key here, as failure rates must be precicely identified and extremely low. And all this with an outstanding power-to-weight ratio.
Power Meets Intelligence
Another trend in system development is apparent: the progressive integration of information and communication technology.
On-board power grids for aircrafts and vessels are comparable with the local power grid of a small town in terms of their complexity and dimensions. The grids connect many distributed sources and loads via long cables and transfer high power simultaneously. As a result, the focus is shifting to grid stability and droop control, i.e. the control and synchronization of generators and converters. Additional functions for monitoring, management and communication, as well as intelligent capabilites need to be implemented in the grids: On-board grids are evolving into smart grids. In stationary grid technology, especially in smart grids or local DC grids, as well as in battery systems for battery management, this transformation has been visible for a while now.
The fusion with data processing requires an increasing integration of digital technology components. Microcontrollers and system on chips have long been used in drivers and control circuits for electronic power switches. Approaches from classic signal processing are also being applied, e.g., for forming the alternating current waveform to save space and material-intensive passive filter components. This is also exemplified by modular multi-level converters, which consist of a large number of freely configurable inverter cells and can be used to cover a very wide range of applications and performance.
The Perfect Match
A new class of intelligent power electronics with additional AI functionality, the so-called cognitive power electronics, is currently being developed further. These "perceptive systems" are equipped with sensors to detect various physical parameters and embedded electronics to record and analyze data in real time. Electric drives thereby become integrated intelligent systems that know about their present operating status. Based on methods of machine learning, cognitive power electronic systems can make predictions and react autonomously to internal and external influences and events.
The high demands imposed by system developers affect all stages of the power electronics value chain. It is already apparent today that the demanded performance characteristics of the new type of power electronics can no longer be achieved with the existing semiconductor devices and system features. Power semiconductors based on ultra-wide bandgap materials and other innovative devices, such as integrated snubbers or active circuit breakers, are in the pipeline. Accompanying, the transition towards an all-electric society pushes the power electronic systems development to new performance levels.
The integrated power electronic system – the symbiosis of innovative power semiconductor technologies, microelectronics and artificial intelligence – is becoming a reality.
PCIM Europe 2024 Nuremberg – Excelling in Power Electronics
At this year’s leading trade fair for power electronics in Europe – PCIM Europe 2024 in Nuremberg – three Fraunhofer Institutes are teaming up at their joint booth no. 6-368. From June 11 to 13, 2024, the Fraunhofer IISB, Fraunhofer ISIT and Fraunhofer IMS together present the entire value chain for next-generation power electronics.
Visitors can expect exhibits on topics ranging from wide-bandgap and ultra-wide-bandgap semiconductors, (U)WBG-ready packaging and module technology, cryogenic to high-temperature, integrated passives, active fuse components, advanced sensor technology, MEMS integration, ultra-compact power converters and modular multi-level converters to electric powertrains for large-scale drives.
PowerCare – Cognitive Power Electronics with Integrated Failure Protection
The centerpiece of the joint booth and overlap of the expertise of the three partner institutes is the exhibition area for project PowerCare. PowerCare uses a new monitoring concept in the form of a miniaturized motor controller with integrated real-time failure prediction (edge AI) to detect upcoming maintenance needs in advance. This is laying the foundation for a new evolutionary stage of intelligent power modules. Simultaneously, the switch to vertical GaN MOSFETs allows for unrivaled power densities and ruggedness.
Within the project, Fraunhofer ISIT works on novel, vertical GaN trench MOSFETs and their behavioral models. Fraunhofer IMS contributes embedded AI models integrated in a PWM controller for failure prediction of electric motors and GaN power semiconductors. Fraunhofer IISB demonstrates GaN MOSFETs and an intelligent motor control with AI-based condition monitoring of the electric drive. For a market-oriented development of cognitive power electronics, the project partners Siemens AG, X-FAB Dresden GmbH & Co. KG, NXP® Semiconductors Germany GmbH, and TU Dortmund University provide support and valuable practical feedback.
Fraunhofer Institute for Integrated Systems and Device Technology IISB
The Fraunhofer IISB in Erlangen specializes in wide-bandgap semiconductors and efficient power electronics. Here, materials and device know-how merges with complex system development, especially for e-mobility and sustainable energy supply. With its solutions, the institute has been setting benchmarks in energy efficiency and power density, even for extreme operating conditions like in aviation and space.
At its long-time no. 1 trade fair, the IISB shows the broad spectrum of its activities in high-performance power electronics. Starting from WBG and UWBG base materials over semiconductor technology with SiC device development and prototype processing, the spectrum ranges to hybrid integration, packaging and module technology. In the area of system integration, visitors await exciting exhibits showcasing medium voltage electronics and advanced SiC and GaN power electronics for automotive, maritime and aircraft applications. Special highlights are a fully integrated aircraft power train in the megawatt class and a crewless electric vertical take-off and landing vehicle for early AI-based forest fire detection.
https://www.iisb.fraunhofer.de
Fraunhofer Institute for Silicon Technology ISIT
The Fraunhofer ISIT in Itzehoe is one of Europe’s most modern research facilities for microsystems technology and power electronics. At the heart of the institute are its cleanroom facilities, large enough not only to conduct research but also to manufacture the microchips developed on an industrial scale.
At PCIM 2024, Fraunhofer ISIT gives insights into current and future activities in the areas power electronics and electronic energy systems. As a part of Fraunhofer’s GaN pilot line, an emerging, independent ecosystem for development activities ranging from epitaxy via device processing to application, the ISIT presents lateral and vertical GaN devices and its processing capabilities as well as GaN-on-QST services. With the concept Active Reliability, the institute shows condition monitoring techniques and data processing approaches such as data-fusion and digital twin for online state-of-health estimation, lifetime extension, and fault tolerance. Further highlights are the EnergyHub, a DC power router for multi-source integration and high-availability power supply and GaN-based converters for high-efficiency and high-density energy conversion.
https://www.isit.fraunhofer.de
Fraunhofer Institute for Microelectronic Circuits and Systems IMS
The Fraunhofer IMS in Duisburg is a trusted research and development partner for industry. Its goal is to develop customized sensor systems for specific needs in the areas of biomedical sensors, optical systems, open-source semiconductors, embedded AI, technology services and even quantum technology.
At PCIM Europe 2024, Fraunhofer IMS presents innovative technologies in power electronics and RFID technology. The institute also offers solutions in ASIC and chip design as well as CMOS, MEMS and LiDAR. Its RISC-V processors deliver outstanding performance and improve efficiency and reliability in various applications. With the PredictiveBoX developed at the IMS, AI-based vibration analysis can be carried out and production optimized. In addition, customized vertical GaN switches enable savings of megatons of CO2.
Research Fab Microelectronics Germany
The overall framework is the Research Fab Microelectronics Germany FMD (acronym in German), a cooperation of the Fraunhofer Group for Microelectronics with the Leibniz institutes FBH and IHP. With more than 4,600 employees and a diversity of expertise and infrastructure, the virtual umbrella organization of FMD is the largest association of its kind in Europe. As a pioneer in cross-location and cross-technology cooperation, FMD is actively addressing the current and future challenges of electronics research to ensure the preservation and expansion of Germany’s and Europe’s technological sovereignty.
The Fraunhofer Institute for Integrated Systems and Device Technology IISB is one of Europe’s leading research institutions for wide-bandgap semiconductors and power electronics, covering the complete value chain. The spectrum ranges from basic materials, semiconductor devices and process technologies, power electronic modules and components to complete power electronic and energy systems.
Main target applications of the IISB are semiconductor manufacturing, electromobility, aerospace as well as sustainable energy supply. With its solutions, the institute has been setting benchmarks in energy efficiency and performance, even for extreme operating conditions. The integration of intelligent data-based functionalities also continuously opens up new application scenarios.
Fraunhofer IISB supports its customers and partners worldwide in transferring scientific results into commercial products. Its activities are organized in two business areas: Semiconductor Technology and Power Electronic Systems. A total of around 300 employees works at the headquarters in Erlangen, Bavaria, and at the Fraunhofer Technology Center High Performance Materials THM in Freiberg, Saxony.
Fraunhofer-Institut für Integrierte Systeme und Bauelementetechnologie IISB
Schottkystraße 10
91058 Erlangen
Telefon: +49 (9131) 761-0
Telefax: +49 (9131) 761-390
http://www.iisb.fraunhofer.de
Abteilungsleiter
Telefon: +49 (9131) 761-139
Fax: +49 (9131) 761-312
E-Mail: bernd.eckardt@iisb.fraunhofer.de