• A
  • A
  • A
  • ABC
  • ABC
  • ABC
  • А
  • А
  • А
  • А
  • А
Regular version of the site

New Development by HSE Scientists Helps Design Reliable Electronics Faster at a Lower Cost

New Development by HSE Scientists Helps Design Reliable Electronics Faster at a Lower Cost

© iStock

Scientists from HSE MIEM have developed a new approach to modelling electrothermal processes in high-power electronic circuits on printed circuit boards (PCB). The method allows engineers to quickly and accurately predict how electronic components heat up during operation, helping prevent overheating and potential failures. The results have been published in Russian Microelectronics

When electric motors or other equipment operate, their electronic components—especially transistors—can become very hot, because heat is inevitably generated as electric current flows through them. When the device is switched on and off, sudden temperature changes occur, which alter the parameters of the transistors and may ultimately lead to equipment failure. 

To prevent this, it is important to accurately predict how an electronic component will heat up and cool down under real operating conditions. This makes it possible to properly design the device and its cooling system, reduce the load on individual components, and extend the service life of the equipment.

Today, engineers use two main approaches to predict equipment overheating. The first is detailed numerical 3D modelling of thermal processes using software packages such as Ansys, Flotherm, and COMSOL, among others. This method provides high accuracy but requires significant computing resources and time. The second approach involves calculations in SPICE simulators using simplified thermal models of components and cooling conditions. While faster, it requires time to develop electrothermal models and does not always account for the actual design features of the PCB and the cooling system.

The scientists proposed combining the advantages of both methods: they developed a multilevel automated system in which the COMSOL package is used to model semiconductor devices together with their housings and refine the thermal models of component packages; SPICE is employed to analyse the electrical circuit, including both electrical and thermal descriptions; and ASONIKA-TM is used to simulate the heating of the PCB and calculate component temperatures. Additionally, the researchers developed special software tools that automate the calculation of component capacitances and transfer data on component temperatures between different calculation modules. This means that additional modules were used to link previously separate software packages, speeding up the calculations. As a result, the process of creating electrothermal models of high-power components for electrothermal simulations became five to ten times faster compared to manual construction of electrothermal circuits.

The scientists at HSE MIEM tested the new technique on a real PCB design for controlling a power stepper motor, a device that regulates the motor’s rotational speed. The board contains high-power MOSFET transistors, which become very hot during operation. The results of the thermal modelling were compared with thermal imaging measurements and showed a close match. 

Igor Kharitonov

'We have observed in practice that our calculations closely match real thermal imaging measurements. This means that the methodology works correctly and can be applied to real engineering tasks,' concluded Igor Kharitonov, Professor at HSE MIEM and co-author of the study.

According to Prof. Kharitonov, such calculations previously required lengthy manual adjustments and a significant investment of time.

'Now we can predict when the board will overheat five to ten times faster and promptly adjust the design and cooling conditions, all while reducing development costs,' he emphasised.

The new technique enables engineers to identify design weaknesses more quickly, optimise cooling systems, and improve equipment reliability. This is particularly important for industrial machinery, power electronics, transportation, and other systems where component failure can have serious consequences.

The study was carried out as part of HSE University's 'Digital Transformation: Technologies, Effects, and Performance' project under the Priority 2030 programme.

See also:

HSE Develops App for Assessing Phonological Processing in Children

Researchers at the HSE Centre for Language and Brain have developed a new digital tool for assessing children's phonological processing skills—the ZARYA (Sound Analysis of the Russian Language) test battery. It is the first standardised application in Russia designed to provide a fast and reliable assessment of children's ability to distinguish speech sounds, retain them in working memory, and perform phonemic analysis. The app runs on Android tablets and smartphones and is available for download from RuStore. Details of the test validation have been published in the Journal of Speech, Language, and Hearing Research.

Researchers Discover How Spelling Errors Slow Down Reading in Russian

Psycholinguists from the Centre for Language and Brain at HSE University–St Petersburg have shown that words that are frequently misspelled are processed more slowly by readers, even when presented with the correct spelling. The researchers confirmed this effect for the first time using Russian-language materials and found that response speed is most strongly linked to how confidently individuals can distinguish the correct spelling of a word from an incorrect one. The study has been published in The Mental Lexicon.

Scientists Discover Why Europium 'Misbehaves'

Europium is a rare-earth metal responsible for the pure red glow in displays and other luminescent materials. For a long time, however, it refused to emit light when surrounded by certain organic molecules known as acylpyrazolone ligands. Chemists have now uncovered the reason: in europium complexes with these ligands, a 'black window' appears—a charge-transfer state in which the energy absorbed by the ligand is dissipated as heat rather than emitted as light. Understanding this mechanism opens the way to designing more efficient red-emitting materials for displays, fluorescent thermometers, and chemical sensors. The results have been published in Dalton Transactions.

HSE Economists Reveal How the Wage Gap Emerges Among Vocational School Graduates

HSE researchers examined the careers of 600,000 graduates of Russian secondary vocational education programmes and found that at the start of their careers, the gender wage gap reaches 23%, doubling after three years. This disparity is largely due to male and female students choosing different occupations when enrolling in vocational schools. These were the findings made by Sergey Roshchin, Natalya Yemelina, and Ksenia Rozhkova from of the HSE Faculty of Economic Sciences. The article has been published in Educational Studies.

HSE Researchers Make Aldehydes Perform Dual Function

Chemists from HSE University have discovered a way to carry out a reductive addition reaction without using an external reducing agent. Instead, the required 'resource' is supplied by the aldehyde itself, one of the reaction participants. This approach helps prevent unwanted side reactions, reduces toxicity, and simplifies the production and synthesis of organic molecules, including those used in the manufacture of medicines. The study has been published in Journal of Catalysis.

HSE Scientists Explain Why Findings in Autism Research Differ

Researchers from the Cognitive Health and Intelligence Centre at HSE University conducted the first-ever systematic review of studies on the specifics of emotion-from-motion perception in autism. The review showed that differences found between autistic and non-autistic individuals are largely associated with the experimental design and the types of tasks given to study participants. The review findings have been published in Research in Autism.

Tremors: Scientists Develop Method for Real-Time Tracking of Hazardous Underground Vibrations

Researchers from HSE MIEM and IPKON RAS have developed a new mathematical monitoring model that can identify the source of hazardous underground vibrations in real time. The technology could help reduce the risk of damage to buildings, roads, and other infrastructure located near quarries and mining sites. The paper has been published in Russian Mining Industry.

HSE Researchers Determine Which Internet Users Are More Likely to Fact-Check

Researchers at HSE University examined the strategies employed by Russian internet users to verify unreliable information and the factors that motivate them to do so. The study found that more than half of users who encounter potentially false information online attempt to verify it by locating the original source. The likelihood of fact-checking is influenced by several factors, including age, place of residence, social status, information literacy skills, and the use of AI. The findings have been published in Monitoring of Public Opinion: Economic and Social Changes.

Tabular Data Anonymisation Solution for Safe Use in AI Systems Developed at HSE University

The AI and Digital Science Institute at the HSE Faculty of Computer Science has developed a tabular data anonymisation service designed to prepare corporate datasets for use in analytics and AI applications. The solution can identify personal data in structured datasets, apply consistent and reproducible anonymisation rules, and generate the artifacts required for quality control, auditing, and subsequent use of data in secure environments.

Population Lifespan Is Governed by Mathematical Laws

Researchers at HSE University and MSU have established a universal law governing the time to extinction of a population in a random environment. Their analysis of the evolution of branching processes—complex probabilistic systems—shows that, regardless of the initial population size, extinction follows strict mathematical laws. The results have been published in the Journal of Applied Probability.