Tech bytes for tea?

In this month’s technology opinion leader column from Keysight Technologies, Hwee Yng Yeo shares her insights into how digital twins can help bring new products to market faster, without compromising on conformance to standards for performance and safety.

Digital twin technology is changing how the automotive industry designs and tests products and solutions for electromobility (e-mobility).

With pressure to develop more energy-efficient batteries, and a ramp-up in charging infrastructure development, digital twins can help bring new products to market faster, without compromising on conformance to standards for performance and safety.

Emulator Versus Simulator

Digital twins have emerged as a hot technology topic, but the concept has its roots in emulation technology dating back to the early 1990s.

Emulators imitate the behaviour of one or more pieces of equipment, whether an integrated circuit or even an entire piece of equipment and have numerous applications.

But before we look at applying emulation technologies, let’s review the differences between emulators and simulators first.

These two terms are sometimes used interchangeably in engineering, but their definitions are quite distinct.

As an example of a device-under-test (DUT), consider a chip:

Emulation technology has come a long way since its early days, evolving into digital twins that utilise powerful hardware and software for engineers to customise test parameters and emulate different equipment and test scenarios.

Let’s take a deeper dive into how digital twins are used in e-mobility development.

Digital Twins Assume the Roles of EVs and EVSEs

The number of new electric vehicle (EV) models is expected to more than double to over 130 models by 2024.

For EV supply equipment (EVSE) vendors, testing charging stations against actual vehicles is not practical.

Likewise, automotive makers face the challenge of ensuring their electric vehicles conform to differing charging standards around the globe.

Testing their vehicles against real charging stations from all over the world is not feasible.

Charging stations are classified by levels as shown in the table above.

Besides the differences between AC and DC electrical platforms, both electric car makers and EVSE manufacturers must contend with interoperability and conformance to regulations as they attempt to market their products worldwide.

In the past, engineers conducted manual testing and connected individual car models to various charging stations, each featuring different standards.

In today’s fast-moving market, this test strategy is no longer feasible.

This is where digital twins come in, automating the tests for different charging interfaces and checking the interoperability between each vehicle and charging station model.

Let’s look at two emulation setups used in today’s EV and EVSE design and test environments.

EV Charging Test

The photo at the beginning of this opinion piece shows a high-power EV test system (centre) with a liquid-cooled charging adapter that emulate DC charging infrastructure.

The electricity for powering the emulated DC charging infrastructure comes from yet another emulator on the left.

The carmaker can now emulate a variety of high-power DC charging infrastructure up to 600 A in less time than connecting the car to multiple charging stations.

EVSE Testing

When testing a charging station design against different cars, a tester with a power supply can emulate an electric vehicle.

The EV digital twin enables the engineer to configure the vehicle to the specifications of different electric cars.

Emulating High-Power Onboard Environment

In addition to EV and charging stations, better and cheaper battery cells are key to driving EV adoption.

Many automakers have specialized teams working on EV energy storage and usage systems to meet these challenges.

Developing and testing new high-power EV batteries requires an intelligent battery management system (BMS).

A BMS performs important safety, control, and regulation functions by monitoring parameters such as voltage, current, temperature, and state-of-charge.

The BMS is also responsible for thermal management, energy management, cell balancing, and performance.

Engineers face a challenging task to validate the BMS’s ability to carry out all these functionalities to specification.

A digital twin environment can help engineers stress test their BMS during development.

This BMS environment emulator can replicate the EV battery cells, emulate failures such as open or short circuits, and even different cell temperatures, to test how the BMS responds to these events.

Inseparable Twin

As the electric vehicle and charging infrastructure market continues to grow, digital twin applications will become an indispensable part of the product development and design validation process.

Digital twins will ensure that their real-world counterparts not only meet industry conformance standards, but also achieve the overarching goal of a greener and more sustainable transport ecosystem.

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This entry was posted on Thursday, December 22nd, 2022 at 4:02 pm and is filed under Automobile, Business IT, Commentary, Enterprise IT, Interview, Keysight, Opinion, Tech Focus, Technology, Trends. You can follow any responses to this entry through the RSS 2.0 feed. You can leave a response, or trackback from your own site.