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Ensuring Reliable AI in Safety-Critical Systems: Challenges and Engineering Solutions
In safety-critical environments, reliability is paramount, and errors have immediate, real-world consequences. If an autonomous system falters in urgent decisions, a clinical support tool misguides diagnoses, or an industrial controller fails in hazardous conditions, the results can be life-threatening. Artificial intelligence must be unwaveringly accurate and reliable at every moment to ensure safety and maintain trust in deployment.
This demands a fundamental shift in AI system engineering. Unlike traditional domains, where model accuracy or benchmark performance may suffice, safety-critical applications require predictable, consistent, and fail-aware behaviour across diverse conditions. The real challenge is to establish AI as fundamentally trustworthy in situations where failure is not an option, making reliability, not just intelligence, the core success criterion.
As AI integrates into mission-critical infrastructure, reliability is not just a technical requirement; it is the foundation and defining goal for deploying AI in safety-critical systems.
The Reliability Gap: From Probabilistic Models to Deterministic ExpectationsA core engineering challenge now demands urgent attention: a deep mismatch exists between traditional system design and modern AI behaviour. Safety-critical systems have historically been deterministic, producing predictable and verifiable outputs. In stark contrast, AI models are inherently probabilistically trained on data, influenced by variability, and alarmingly sensitive to environmental changes.
This mismatch creates a reliability gap that cannot be ignored in high-stakes deployments:
- High accuracy does not ensure safe behaviour in rare or unseen scenarios
- Models may generate confident yet incorrect predictions
- Behaviour under edge conditions remains difficult to anticipate
In safety-critical contexts, such uncertainties quickly become intolerable. Systems must now be engineered not just for performance, but for rigorous assurance under uncertainty. As Sundar Pichai warned, “The more capable AI becomes, the more critical it is to ensure it behaves safely and predictably.” This is no longer a theoretical challenge; it is the defining engineering crisis of our time.
Core Challenges in Deploying Reliable AI SystemsThe dynamic nature of real-world environments directly undermines reliability. AI systems trained in controlled settings inevitably confront distribution shifts at deployment scenarios absent from training data. These shifts degrade performance, especially in rare or safety-critical contexts.
In addition to distribution shifts, another critical issue is the inability of many models to communicate uncertainty. AI systems often produce outputs with high confidence, even when operating outside their domain of competence. In applications involving autonomous control or real-time decision-making, such overconfidence can lead to unsafe outcomes without warning.
Building on the previous concern, explainability is equally important. Safety-critical systems demand traceability and accountability, yet many AI models function as opaque decision-makers. Without the ability to interpret decisions, validating system behaviour and meeting regulatory expectations becomes significantly more difficult.
Finally, AI systems do not operate in isolation. They are part of a broader ecosystem involving sensors, embedded hardware, and control systems. Variability at any of these levels, whether due to sensor noise, latency, or hardware constraints, can influence overall system reliability. Ensuring dependable operation, therefore, requires a holistic, system-level perspective.
When AI Fails: Understanding System-Level RiskFailures in safety-critical AI systems are rarely isolated events. A single incorrect output can propagate across the system, leading to cascading effects that compromise overall functionality.
The most critical risks include:
- Silent failures, where incorrect outputs remain undetected
- Error propagation across interconnected system components
- Over-reliance on AI outputs, reducing effective human oversight
These risks highlight a key engineering principle: reliability must be designed into the system from the outset. It cannot be treated as a post-deployment evaluation metric.
Engineering Reliable AI: From Models to SystemsWe must shift from model-centric development to system-level assurance to address these challenges. We need to embed reliability across the entire lifecycle, from data collection to deployment and monitoring.
A foundational step is robust data engineering. Expand datasets to capture real-world variability. Simulate edge-case scenarios. Continuously monitor for data drift. These approaches improve generalisation and reduce unexpected system behaviour.
Equally important is uncertainty-aware system development. Integrate mechanisms that estimate prediction confidence so that models detect when they exceed their limits. This enables fallback strategies, like deferring to human operators or switching to safe modes. In this way, AI evolves from static prediction to self-aware system components.
Validation methodologies must also evolve. Traditional testing approaches are insufficient for capturing the complexity of AI behaviour. Scenario-based testing, simulation of rare or hazardous conditions, and stress testing under extreme inputs are becoming essential tools for evaluating reliability beyond standard datasets.
Explainability strengthens system assurance. While full transparency is rare, interpretable insights enable debugging, validation, and regulatory compliance. These capabilities help build trust among stakeholders.
Redundancy plays a central role in ensuring reliability. Instead of relying on a single model, systems increasingly incorporate multiple validation layers, hybrid architectures combining AI with rule-based logic, and predefined fail-safe states. As Satya Nadella emphasises, “Trust must be built into every layer of AI systems.” Redundancy ensures that this trust does not depend on a single point of failure.
System-Level Assurance: Beyond the AlgorithmA key realisation in modern engineering is that AI reliability cannot be isolated to the model alone. True assurance requires coordination across the entire system stack, including data pipelines, inference mechanisms, hardware platforms, and control logic.
This has led to the emergence of hardware-software co-design, where AI models are optimised alongside the systems that execute them. In this paradigm, reliability becomes a property of the entire system rather than an attribute of the algorithm alone.
Industry Perspective: Measured Adoption in High-Stakes DomainsAI adoption in safety-critical industries is cautious, driven by the persistent gap between experimental results and proven, production-level reliability.
Organisations are prioritising validation, risk mitigation, and incremental integration over rapid deployment. Hybrid approaches combining AI capabilities with deterministic safeguards are becoming increasingly common, reflecting the need to balance innovation with operational safety.
Regulatory and Certification ChallengesRegulatory frameworks for safety-critical systems were originally designed for deterministic software. Applying these frameworks to AI introduces significant challenges, particularly in verifying non-deterministic behaviour and defining acceptable risk thresholds.
The absence of standardised validation methodologies further complicates certification processes. As a result, the industry is moving toward new assurance models that emphasise transparency, traceability, and continuous validation throughout the system lifecycle.
Future Outlook: Toward Assured and Certifiable AIThe future of AI in safety-critical systems demands convergence. Data-driven intelligence will be fused with rule-based safeguards, and machine learning models will be integrated decisively with formal verification techniques.
Building on this convergence, continuous monitoring and adaptive system design will decisively enhance reliability, ensuring systems respond dynamically to changing conditions. We will deliver not just intelligent systems, but AI that is verifiably safe and certifiable for deployment.
As Jensen Huang states, “AI is advancing rapidly, but reliability and safety must scale with it.” This balance will define the next phase of AI engineering.
Conclusion: Reliability as the Foundation of Trustworthy AIAs AI expands into safety-critical domains, the definition of success is being redefined. Performance alone is no longer sufficient. Systems must demonstrate predictable behaviour under uncertainty, transparency in decision-making, and resilience in the face of failure.
AI must be engineered as a dependable system component, fully integrated into a broader safety and assurance framework. In this evolving landscape, reliability is not an added feature; it is the foundation upon which trust is built.
The trajectory of AI in safety-critical systems hinges not just on intelligence, but on how reliably these systems earn trust when it matters most.
The post Ensuring Reliable AI in Safety-Critical Systems: Challenges and Engineering Solutions appeared first on ELE Times.
Nanometer Nanotubes for Future Electronics
Researchers in Japan creates the world’s smallest semiconducting nanotubes, structures 100,000 times thinner than a human hair. By growing molybdenum disulfide inside protective tubes of boron nitride, researchers, including those from the University of Tokyo, produce highly uniform tubes just 1 nanometer wide, a scale at which it’s difficult to make stable nanotube structures. The work confirms decades-old theoretical predictions about how these ultrafine materials behave and could also provide a new route toward miniaturized electronic devices.
A few years back, carbon nanotubes were attracting a lot of press attention. But there’s a new contender in the ring, and it offers some advantages over its carbon counterpart that could tempt engineers to design products around it. Molybdenum disulfide (MoS2) nanotubes, though still experimental in nature, point to applications in semiconductor electronics, high-resolution sensing, and quantum-scale physics research.
“We achieved the synthesis of atomically precise semiconducting nanotubes with nanometer diameters. The coaxial structure, where a semiconducting MoS2 nanotube is surrounded by an insulating boron nitride (BN) nanotube, is attractive for gate-all-around transistors, one of the most advanced transistor architectures,” said Associate Professor Yusuke Nakanishi from the Department of Advanced Materials Science at the University of Tokyo. “Our paper demonstrates a way for structural control of inorganic semiconducting nanotubes at the atomic scale. And we experimentally demonstrated that the bandgap (related to how materials work as semiconductors) of the nanotubes decreases as their diameters become smaller, in agreement with theoretical predictions proposed more than a quarter century ago.”
Conventional methods for producing nanotubes are usually limited to diameters above 10 nanometers, multiwall concentric tubes, and poorly controlled or irregular atomic structures. Nakanishi and his team synthesized 1-nanometer-wide, single-wall MoS2 nanotubes with well-defined atomic structures. It manages the use of chemical reactions inside the narrow space of BN nanotubes. The confined space constrains the MoS2 nanotubes, which would otherwise be difficult to form, and promotes well-defined atomic arrangements, essential for engineered applications.
“In nanotubes, even small structural differences can strongly affect their properties. If the structure can be precisely controlled, the properties are more consistent, which is essential for reliable and reproducible transistor performance. Their biggest advantage is atomic-level structural control,” said Nakanishi. “Current silicon transistors are typically made by etching bulk silicon, but it’s increasingly difficult to keep their structures perfect at smaller sizes, where defects have a big impact. Carbon nanotubes also face a challenge for transistor applications, since even tiny structural differences can change how they behave, including whether they act more like metals or semiconductors. Our nanotubes could offer a more reliable way to build ultrasmall semiconductor channels with consistent properties.”
Practical applications are likely still some years away, and important challenges remain before working transistor devices can be made. In particular, the team wishes to increase the nanotube length from the current limit of several hundred nanometers to around 1 micrometer (which is 1,000 nanometers, and one-thousandth of a millimeter). Another future direction relates to materials: The method could also enable other inorganic nanotubes, including magnetic and superconducting materials. The researchers hope the work will help expand nanotube science beyond carbon-based systems and open the door to a broader class of atomically accurate nanotube materials for research, sensing, and smaller, faster devices.
The post Nanometer Nanotubes for Future Electronics appeared first on ELE Times.
TIL about SLP - Substrate-Like PCB Technology
| submitted by /u/1Davide [link] [comments] |
Progress V2 -> V3 on our Open Access Health Tracker
| 4 months ago I shared the progress of our Open Access Health Tracker from V1 to V2. Today I wanted to share the progress from V2 to V3 on a schematic level. And it's massive. 3x3cm PCB, 3 meters of traces and maxing the capabilities of JLCPCB. Plus an additional 2-3 PCBs for sensors not shown. Next up SLP instead of PCB. [link] [comments] |
Weekly discussion, complaint, and rant thread
Open to anything, including discussions, complaints, and rants.
Sub rules do not apply, so don't bother reporting incivility, off-topic, or spam.
Reddit-wide rules do apply.
To see the newest posts, sort the comments by "new" (instead of "best" or "top").
[link] [comments]
Automatic turntable that I'm designing from scratch
| I'm designing a fully-automatic turntable from scratch called the Statimatic STM-01, using: - A Teensy 4.1 - Stepper for tonearm elevation - Stepper for tonearm azimuth movement - Stepper for azimuth clutch - Demultiplexer, to split elevation/azimuth stepper signal - Multiplexer, to handle input buttons (like "play" or "pause") - Shift register, to handle output LED statuses The "turntable" part isn't finished yet (nor is the automatic movement), so I'm just using an AR-XA as the turntable for now. I like records, and I like making stuff, so I decided I wanted to make a turntable. I know it isn't practical, but hey, I'm having fun with it! Please excuse the absolute mess that is the wiring. It is open source, though I'm not sure if GitHub links count as self promotion, so I'll play it safe and leave that out. [link] [comments] |
Made my first 8-bit ALU in Logisim Evolution! Next steps: designing the rest of the CPU and then building it IRL on breadboards!
| [group 4b][variant 4b] 0x0_ = MISC submitted by /u/_Favo_
Github repo with all docs and files: https://github.com/mrFavoslav/8bit-cpu-MESAx8 I'll be posting my progress here and on https://www.favoslav.cz/blog/ [link] [comments] |
EEVblog 1753 - Designing a 2000V Isolated Oscilloscope (Cleverscope)
EEVblog 1752 - Texas Instruments screwed up the NE5532
| submitted by /u/1Davide [link] [comments] |
📰 Газета "Київський політехнік" № 21-22 за 2026 (.pdf)
Вийшов 21-22 номер газети "Київський політехнік" за 2026 рік
The RF-ready GaN-on-silicon with lower parasitic losses

A new technology addresses a key performance barrier limiting the use of GaN-on-silicon semiconductors in mainstream RF applications. According to Scott Bibaud, president and CEO of Atomera, this will change the economics of GaN in RF by unlocking breakthrough RF performance on low-cost silicon substrates.
Gallium nitride (GaN) devices for high-performance RF applications are typically built on silicon carbide (SiC) substrates; while they offer robust performance, they are also costly and difficult to scale. On the other hand, silicon substrates offer a lower-cost, more scalable foundation with the potential to support larger wafer sizes and greater compatibility with standard silicon manufacturing.
However, GaN-on-silicon underperforms in RF applications due to parasitic channel losses that reduce efficiency, especially at high frequencies. Enter Atomera’s Mears Silicon Technology (MST), which claims to reduce these losses while offering robust linearity and lower-cost GaN solutions for 5G and other high-frequency RF devices.
MST—a quantum-engineered thin-film technology—introduces a thin, oxygen-modified layer near the surface of the silicon wafer to create a more favorable platform for GaN growth, making silicon a more viable foundation for high-performance RF devices. This controlled layer modifies the silicon lattice structure and helps block the diffusion of electrical dopants. That, in turn, improves crystal quality at the GaN-silicon interface.

MST can improve various wafer-level reliability measures in nitrided oxide planar devices. Source: Atomera
Incize, which provides characterization and modeling services for RF semiconductors, has performed RF characterization of the first MST-enabled samples. The Belgian company reports a substantial reduction in parasitic interface charge and a significant reduction in RF losses.
“Beyond the small-signal improvements, the large-signal results are particularly compelling,” said Mostafa Emam, founder and CEO of Incize. “Then there is a linearity benefit that extends into the high-power regime, approaching performance levels typically associated with advanced RF SOI technologies.”
In Atomera’s own testing, MST enabled more than a 10x reduction in parasitic channel charge, reducing a key mechanism of RF power loss and supporting improved high-frequency GaN device performance. The test data also shows that MST enables devices to handle significant power while maintaining signal quality—linearity—under stress.
Robert Mears, founder and CTO of Atomera, is quick to add that linearity is a top concern for RF designers. “The new data shows MST GaN-on-silicon achieving both the ultra-low RF losses and linearity metrics of advanced trap-rich RF SOI,” he said. “At the benchmark input power of 30 mW, the linearity is exceptional, 1000x better than the GaN-on-silicon reference wafer.”
Atomera, a semiconductor materials and technology licensing company, is based in Los Gatos, California.
Related Content
- GaN on silicon or SiC?
- A Guide to GaN-on-Silicon
- A brief history of gallium nitride (GaN) semiconductors
- Why RF Technologies Should Consider GaN Over Silicon
- GaN-on-Si Technology Makes Headway in RF Applications
The post The RF-ready GaN-on-silicon with lower parasitic losses appeared first on EDN.
South Wales cluster CSconnected issues SIPF program impact report
CSA Catapult translates research into double pulse testing
Scientists discover a Quantum Effect that Eliminate Batteries
Tiny defects inside a quantum material may hold the key to battery-free electronics powered by energy already floating around us. Credit: AI/ScienceDaily.com Scientists have uncovered a new way to control an unusual quantum phenomenon that could one day help power electronic devices without batteries.
An international research team led by Professor Dongchen Qi from the Queensland University of Technology (QUT) School of Chemistry and Physics and Professor Xiao Renshaw Wang from Nanyang Technological University in Singapore investigated the physics behind the nonlinear Hall effect (NLHE), a quantum phenomenon with significant potential for future energy-harvesting technologies.
Unlike the classical Hall effect, the NLHE can convert alternating electrical signals directly into direct current. This means energy from wireless transmissions or other ambient sources could potentially be transformed into usable electricity without relying on conventional diodes or other bulky electronic components. The NLHE is a sophisticated quantum phenomenon in condensed matter physics where a voltage is generated perpendicular to an applied alternating current, even in the absence of a magnetic field, Professor Qi said.
“This effect allows us to convert alternating signals straight into direct current, which is what’s needed to power electronic devices. In principle, it means sensors or chips that could operate without batteries, drawing energy from their environment.”
Quantum Material Shows Stable Performance at Room Temperature
To better understand how the effect works, the researchers examined a high-quality topological material known for its unusual electronic behavior. Their experiments showed that the nonlinear Hall effect remains stable even at room temperature, an important step toward practical applications outside the laboratory. The team also discovered that temperature plays a key role in determining both the strength and direction of the electrical voltage produced by the material.
How Defects and Atomic Vibrations Control the Effect
At lower temperatures, tiny imperfections within the material had the greatest influence on the quantum effect. As temperatures increased, naturally occurring vibrations in the crystal structure became more important. This shift caused the direction of the generated electrical signal to reverse, revealing a previously unseen mechanism for controlling the phenomenon.
“Once you understand what’s happening inside the material, you can design devices to take advantage of it,” Professor Qi said.
That’s when quantum effects stop being abstract and start becoming useful — supporting future applications ranging from self-powered sensors and wearable technology to ultra-fast components for next-generation wireless networks. The findings provide new insight into how quantum materials behave and could help researchers develop smaller, faster, and more energy-efficient technologies that harvest power from their surroundings.
The post Scientists discover a Quantum Effect that Eliminate Batteries appeared first on ELE Times.
How to design a digital-controlled PFC, Part 4

Editor’s note: This is a multi-part series on how to design a digital-controlled PFC. Previous entries:
- How to design a digital-controlled PFC, Part 1
- How to design a digital-controlled PFC, Part 2
- How to design a digital-controlled PFC, Part 3
High efficiency is a mandatory requirement in some applications, especially in data centers. The recently announced 80 Plus Ruby certification sets the highest efficiency standard for data center power-supply units (PSUs), as shown in Table 1. The new efficiency requirement is not only higher than 80 Plus Titanium at each load condition, but also requires 90% efficiency at a 5% load, which has never been specified before.
|
80 Plus test type |
230V internal redundant |
||||
|
Percentage of rated load |
5% |
10% |
20% |
50% |
100% |
|
80 Plus Titanium |
90% |
94% |
96% |
91% |
|
|
80 Plus Ruby |
90% |
91% |
95% |
96.5% |
92% |
Table 1 “Ruby” is the most recent and most stringent of the 80 Plus certification levels
With totem-pole bridgeless power factor correction (PFC) offering the best efficiency among all PFC topologies, digital control can further push the efficiency capabilities of this topology to new levels. In the fourth and final installment of this series, I will first introduce several digital methods to improve efficiency and then discuss some special PFC requirements including re-rush current control, electrical metering (e-metering) and PFC with a baby boost converter.
Dynamic dead time to achieve ZVS for synchronous switchTheoretically, the PFC synchronous switch can operate with zero voltage switching (ZVS), but there must be a proper dead time between when the boost switch turns off and the synchronous switch turns on. As illustrated in Figure 1, assuming a positive cycle, when boost switch Q2 turns off, the inductor current (IL) starts to charge the output capacitance (COSS) of Q2 and discharge the output capacitance COSS of Q1, and the switch-node voltage rises.
If Q1 turns on before the switch-node voltage rises to the output voltage (VOUT), this is hard switching, and the switching losses are high. If Q1 turns on too late after the switch-node voltage rises to VOUT, the current will conduct in the third quadrant of Q1 with diode-like behavior. Since the gallium nitride field-effect transistor used for Q1 has a higher VSD drop compared to a silicon metal-oxide semiconductor field-effect transistor body diode, this induces a higher third-quadrant conduction loss.

Figure 1 This equivalent circuit describes a PFC synchronous switch during dead time. (Source: Texas Instruments)
Ideally, Q1 should turn on at the exact moment when the switch-node voltage rises to VOUT. Given the IL, VOUT and COSS of Q1 and Q2, the following equation calculates the time to charge the switch node from 0 to VOUT:
You can use firmware to dynamically adjust the dead time calculated from the equation to maintain ZVS for the synchronous switch.
CCM_TCM multimode controlA totem-pole bridgeless PFC can operate in either continuous conduction mode (CCM) or triangular current mode (TCM); each has its advantages and disadvantages. Table 2 provides a high-level comparison between the two modes.
|
|
CCM operation |
TCM operation |
|
Pros |
|
|
|
Cons |
|
|
Table 2 Continuous conduction mode (CCM) and triangular current mode (TCM) options both have pros and cons for totem-pole power factor correction (PFC) operation purposes.
Ideally, the totem-pole bridgeless PFC could operate with multimode, as shown in Figure 2. At heavy loads or at the peak of an AC half cycle, the desired PFC input current is high and the PFC operates in CCM mode. When the load reduces or around the AC zero-crossing area where the desired PFC input current is low, the PFC switches to TCM mode and operates with ZVS.
Compared to pure CCM mode, this multimode operation has better efficiency at light loads because of ZVS. Compared to pure TCM mode, because the inductor current ripple is much lower, there is no need to use multiphase interleaved operation; therefore, this multimode operation significantly reduces the size and system costs. By combining the advantages of both CCM and TCM, this multimode operation can meet both high-efficiency and high-power-density requirements.

Figure 2 CCM_TCM multimode operation can meet both high-efficiency and high-power-density requirements. (Source: Texas Instruments)
Reference 1 provides details about this control method and its implementation. Figure 3 compares the efficiency (tested on the same board) between this CCM_TCM multimode control method and traditional CCM control, with efficiency improving as much as 2%.
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| (a) | (b) |
Figure 3 CCM_TCM multimode control delivers efficiency improvements versus traditional CCM control in both low line (a) and high line (b) environments. (Source: Texas Instruments)
Special burst mode – AC cycle skippingBurst mode is widely used to improve efficiency at light loads. Unlike traditional pulse-width modulation (PWM) pulse-skipping burst mode, where you skip PWM pulses randomly, here I would like to introduce a special burst mode: AC cycle skipping, which is you skip one or more AC cycles in light loads.
In other words, you would turn the PFC off for one or more AC cycles and turn the PFC back on for the next AC cycle. The turnon and turnoff instance occurs at the AC zero crossing such that the whole AC cycle is skipped. Since PFC turnon and turnoff at inductor current equal zero, there is less stress and electromagnetic interference.
The number of AC cycles to skip is reverse-proportional to the load; the lighter the load, the more AC cycles skipped. Figure 4 shows the skipping of one and two AC cycles, respectively. Channel 1 is the AC voltage, and channel 4 is the AC current.
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| (a) | (b) |
Figure 4 Shown here is AC cycle skipping at a light loads: one cycle (a) and two cycles (b). (Source: Texas Instruments)
Once the PFC turns off, the switching losses, driving losses and reverse-recovery losses all drop to zero, and the power losses are just the PFC standby power.
When turning off the PFC to skip AC cycles, both the current loop and voltage loop need to be frozen; otherwise, the integrators in those loops will build up to generate a big PWM pulse when the PFC turns back on, causing a large current spike.
Determining whether the PFC enters a light load requires the load information. Normally there is no current sensor at the PFC output; therefore, it’s not possible to directly measure the output load. However, because the PFC voltage-loop output is proportional to the load, you can use the voltage-loop output as a rough indicator to determine whether the PFC is operating with a light load.
If you must precisely skip an appropriate number of AC cycles to maintain VOUT ripple within a specified range, you will need accurate load information, which you can obtain through an integrated e-meter function that I will discuss after the next section.
A big concern with AC cycle skipping is the VOUT drop during a load transient. Assuming that a load step-up occurs when the PFC is off, VOUT may drop too much.
To address this issue, you can compare VOUT to a predefined threshold through a comparator. Once VOUT is below this threshold, the PFC will immediately exit burst mode, disable AC cycle skipping, and return to normal operation. The PFC will handle the transient response as if there is no such special burst mode.
AC cycle skipping can also help reduce total harmonic distortion (THD) at light loads. Reference 2 compares THD with and without this method.
Re-rush current limitThe AC input voltage could suddenly drop out when PFC is operating normally. Since the load is still applied, the PFC VOUT could drop to a lower value. Then, when the AC voltage returns, if the AC input voltage is higher than VOUT, there will be an inrush current. This current is called the re-rush current.
Previously, the re-rush current was unspecified and there was no special control action for this event, it solely relied on the power-stage components’ ability to handle re-rush current. Test results show that re-rush current can jump more than 10 times higher than the PFC-rated maximum input current. Such a high re-rush current can either damage the power supply or reduce its lifetime.
The recently released Modular Hardware System– Common Redundant Power Supply (M-CRPS) specification requires limiting re-rush current when the input voltage resumes after an input brownout or blackout event on the power supply used in a data center. As shown in Figure 5, the root-mean-square (RMS) value of re-rush current should not exceed 5 times the maximum PSU rating over one-half cycle of input frequency, or 3.5 times the maximum PSU rating over one cycle of input frequency. In addition, the input current of the PSU should settle to a value less than or equal to two times the maximum PSU rating of the PSU within two cycles of the input frequency after applying the AC input.

Figure 5 The Modular Hardware System– Common Redundant Power Supply (M-CRPS) specification documents limits on both re-rush current and timing. (Source: Texas Instruments)
Reference 3 provides a firmware-based solution to handle this re-rush current so that when the AC voltage comes back from dropout, both the re-rush current (when VIN > VOUT) and the non-re-rush current (when VIN < VOUT) are well controlled – not exceeding the M-CRPS limit specification, but high enough to rapidly boost VOUT.
E-meteringPower supplies in data centers are required to measure the input power in real time and report the measurement to the host; this is called e-metering. The M-CRPS specification requires an input power measurement error within ±1% when the load is >125W, within ±1.25W when the load is between 50W and 125W, and within ±5W when the load is <50W. To achieve such high measurement accuracy, the e-meter function is traditionally implemented through a dedicated metering device, as shown in Figure 6a.
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| (a) | (b) |
Figure 6 These circuit diagrams show a traditional e-meter and PFC control (a), as well as combining an e-meter with PFC control (b). (Source: Texas Instruments)
A current shunt placed on the PFC input side senses the input current, with a voltage divider (not shown in Figure 6a) across the AC line and AC neutral senses the input voltage. A dedicated metering device receives this current and voltage information and calculates the input power and input RMS current information, sending the results to the host.
With a digital controller, since analog-to-digital converters (ADCs) of the microcontroller (MCU) are measuring both the input voltage and input current, it becomes possible to integrate the e-meter function into PFC control code. Figure 6b shows this e-meter configuration.
A current shunt senses the input current and an isolated delta-sigma modulator (the AMC1306 from Texas Instruments) measures the voltage drop across the current shunt. The delta-sigma modulator output is sent to the PFC controller MCU. The current information will be used for both e-metering and PFC current-loop control. A voltage divider senses the input voltage, which is then measured by the MCU’s ADC directly, just as in traditional PFC control. Reference 4 has more details about e-meter implementation and calculation.
Integrating e-meter functionality into PFC control code eliminates the need for a dedicated metering device, not only reducing system costs, but also simplifying printed circuit board layout and expediting the design process.
PFC with a baby boost converterIn server applications, a bulk capacitor (CBULK in Figure 7) is required to hold PSU output in regulation for more than 10mS after AC dropout. To accomplish this, a 3kW server PSU would need a total capacitance of over 1.3mF, which would consume at least 30% of the overall space. To improve power density, you must reduce the bulk capacitance.
Adding a baby boost converter between PFC and DC/DC, as shown in Figure 7 and described in Reference 5, can achieve high power density. The baby boost converter is a compact boost converter that only operates during AC dropout events.

Figure 7 A PFC with a baby boost converter can achieve high power density. (Source: Texas Instruments)
Figure 8 is a flow chart of baby boost converter operation. During normal operation, the baby boost converter is off and bypassed by a BYPASS FET Q4. When AC line dropout occurs and VBULK drops to a certain level, Q4 turns off, and the baby boost converter turns on to allow VBB to maintain its nominal value. If AC power returns, VBULK will rise; once VBULK rises to a certain level, MCU turns off the baby boost converter, turns on BYPASS FET Q4, and the PFC resumes normal operation.

Figure 8 This flow chart outlines the various stages of baby boost converter operation.
I hope that the information imparted in this series enables you to design your own digital-controlled PFC and meet ever-more-strict specifications. You will find that digital control is so flexible that is possible to implement advanced control algorithms that would be difficult to implement with analog control. A digital-controlled power supply also offers impressive performance.
References
- Sun, Bosheng. “A novel CCM-TCM multimode control method for totem-pole bridgeless PFC.” Texas Instruments Analog Design Journal article, literature No. SLYT877, 1Q 2026.
- Sun, Bosheng. “AC cycle skipping improves PFC light-load efficiency.” Texas Instruments Analog Design Journal article, literature No. SLYT585, 3Q 2014.
- Sun, Bosheng. “How to limit PFC re-rush current.” Texas Instruments Analog Design Journal article, literature No. SLYT865, 1Q 2025.
- Sun, Bosheng. “A low-cost and high-accuracy e-meter solution.” EDN, Aug. 26, 2024.
- Yu, Sheng-Yang, Benjamin Genereaux, and LiehChung Yin. “Improve power density with a baby boost converter in a PFC circuit.” Texas Instruments Analog Design Journal article, literature No. SLYT830, 2Q 2022.
Related Content
- How to design a digital-controlled PFC, Part 1
- How to design a digital-controlled PFC, Part 2
- How to design a digital-controlled PFC, Part 3
- A low-cost and high-accuracy e-meter solution
The post How to design a digital-controlled PFC, Part 4 appeared first on EDN.
India’s Electronics Boost: SMT Expansion & Strategic Localization
India’s electronics manufacturing and design ecosystem marks a major infrastructure milestone with the inauguration of VVDN Technologies’ state-of-the-art Surface Mount Technology (SMT) line and Mechanical Innovation Park in Manesar. The launch highlights a broader structural shift in the nation’s industrial capacity, driven by targeted policy frameworks like the Make in India initiative.
According to data shared by Electronics and IT Minister Ashwini Vaishnaw during the deployment event, the sector’s manufacturing output has scaled fivefold over the last decade. This production surge is closely paired with an aggressive outward trade trajectory; electronics exports scaled six times over the same ten-year period, officially crossing the ₹3,25,000 crore threshold.
Deepening the Component Ecosystem
To transition from system-level assembly to deep-tech component localization, the government recently greenlit a dedicated electronic component manufacturing scheme. This policy framework is engineered to structurally mature the domestic supply chain, mitigate dependencies on imported sub-assemblies, and catalyze industrial workforce expansion. Currently, the electronics manufacturing sector accounts for an employment base of approximately 25 lakh individuals.
IP Safeguards and Supply Chain Resilience
Minister Vaishnaw emphasized that international hardware brands are increasingly anchoring their production pipelines in India due to two main technical and regulatory pillars:
- Enhanced Product Quality Standards: Rising yields and tighter quality control metrics across domestic fabrication and assembly lines.
- Robust Intellectual Property (IP) Safeguards: Tighter legal and technical frameworks protecting proprietary design architectures.
The state’s forward-looking roadmap relies on an integrated stack combining design-led innovation, manufacturing scaling, specialized technical skilling, and trusted hardware innovation. To secure long-term operational resilience against global market disruptions, India is actively focusing on securing diverse rare earth supply chains, establishing a trusted hardware baseline anchored tightly to IP protection and advanced engineering.
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Enhancing Power Stability in AI-Driven Data Centres: Emerging Engineering Approaches
Introduction: When Power Defines the Limits of AI
As artificial intelligence expands across industries, the focus has shifted from just computing performance. Now, power systems under high-density AI infrastructure are the main constraint. Modern data centres with accelerator-rich clusters have intense and highly variable power demands.
When thousands of processing units ramp up at once, even millisecond-scale fluctuations in power delivery can ripple across racks, affecting performance and system stability. In such environments, power is not just a utility; it is a key determinant of operational reliability and scalability.
This shift is transforming data centre engineering. Jensen Huang says, “AI data centres are fundamentally different; they require new architectures for computing, networking, and power.” Power system transformation now drives the next generation of AI workloads.
The Evolving Power Profile of AI Workloads
AI workloads create distinct electrical behaviour compared to traditional enterprise applications. They rely on synchronised processing, with multiple accelerators running in parallel and quickly shifting between low and peak utilisation. These shifts cause sharp transient loads that immediately stress the power delivery network.
From an engineering standpoint, this poses two challenges. Infrastructure must deliver sustained power throughout training cycles and respond instantly to fluctuations while maintaining stable voltage. These demands set strict requirements for the entire power chain, from facility-level supply to board-level voltage regulators.
Power delivery now focuses on responsiveness, stability, and coordination, not just capacity.
Core Challenges in Maintaining Power Stability
A key challenge is managing transient load response. When multiple accelerators increase power draw simultaneously, the system must maintain stable voltage levels despite demand spikes. Any delay or inefficiency in response can cause voltage droop, affecting performance and stressing electrical components.
High-density deployment is also a major issue. AI-focused racks concentrate large power demand in tight physical spaces, making power distribution more complex. This concentration increases reliance on efficient conversion stages and highlights inefficiencies in traditional power architecture. Workload variability complicates the scenario. Training workloads, which involve running machine learning models to improve their performance, sustain high power consumption over long periods. Inference workloads, which use trained models to make predictions or classifications, create intermittent, bursty demand. At scale, these differences produce unpredictable aggregate loads that challenge conventional provisioning.
Overlaying these challenges is the tight coupling between power and thermal behaviour. As power increases, heat rises. This raises cooling requirements. This interdependency forms a feedback loop. Inefficiencies in one domain amplify stress in the other, so coordinated design is essential.
When Power Instability Becomes System Risk
In AI-driven environments, power instability does not remain localized; it propagates through the system, often with compounding effects. Even minor inconsistencies in power delivery can trigger a chain of operational issues, including:
- Accelerator throttling, reducing computational efficiency
- Node-level interruptions that disrupt distributed workloads
- Thermal stress escalation, impacting hardware reliability
- Increased overhead in workload redistribution and recovery
Such events may not always lead to immediate failure, but they degrade system performance and resilience over time. This makes it clear that power stability must be engineered proactively, rather than treated as an afterthought.
Engineering Approaches to Strengthen Power Stability
Addressing these challenges requires a shift to integrated, system-level engineering. The transformation begins with redesigning power-delivery architectures. Modern systems are optimised to improve transient response and maintain stable voltage levels under rapidly changing load conditions. Enhanced conversion efficiency and improved distribution reduce losses and maintain consistency.
Real-time monitoring and adaptive control are just as vital. By continuously tracking power use across nodes and racks, data centres can spot anomalies early and automatically adjust power allocation. This makes power management a dynamic, intelligent system rather than a static provisioning task.
Another critical advancement lies in workload-aware orchestration. Rather than treating compute demand as separate from infrastructure constraints, modern systems align workload scheduling with power availability. Distributing tasks more intelligently and avoiding synchronised demand peaks helps operators maintain a balanced, stable power profile.
To manage upstream variability, data centres are adding energy buffering solutions. Short-term storage helps absorb sudden spikes and smooth out power fluctuations. This decouples compute demand from instant grid changes, improving resilience and ensuring continuity during disturbances.
At a broader level, the integration of hardware and software design is becoming indispensable. Accelerators are being optimised for energy efficiency, while orchestration layers increasingly incorporate power-awareness into scheduling decisions. As Satya Nadella has emphasised, “Every layer of the computing stack must evolve to meet the demands of AI.” Power infrastructure is now a critical part of this evolution.
Power as a First-Class Resource
A defining shift in AI data centre design is recognising power as a first-class system resource, equal to compute and memory. This view requires coordinated management of compute clusters, networking, cooling systems, and energy delivery.
By treating power as a shared and dynamic resource, operators can optimise utilisation, reduce localised stress points, and improve overall system efficiency. This integrated approach represents a departure from traditional designs, in which power was often treated as a fixed constraint rather than an actively managed variable.
Industry Direction: Scaling Within Constraints
As organizations expand AI infrastructure, a clear divergence is emerging. Hyperscale operators are investing in purpose-built architectures designed to handle high-density, high-variability workloads. In contrast, many enterprise data centres are adapting existing infrastructure, often encountering limitations in power delivery and cooling capacity.
At the same time, sustainability considerations are becoming increasingly prominent. Energy efficiency is no longer optional—it is a critical factor influencing design decisions. This convergence of performance, reliability, and sustainability is shaping the next phase of data center evolution.
Future Outlook: Toward Autonomous Energy Management
Looking ahead, the future of AI-driven data centres lies in intelligent, self-regulating power systems. These systems will leverage predictive models to anticipate workload-driven demand, dynamically optimize energy distribution, and integrate seamlessly with evolving energy sources. In this emerging paradigm, AI will play a dual role-not only driving demand but also enabling smarter infrastructure management. As Sundar Pichai has noted, “AI will shape the infrastructure that powers it.” This feedback loop will define the trajectory of next-generation data centres.
Conclusion: Power Stability as the True Constraint of AI Growth
AI’s rapid progress brings huge computational power, but also exposes a major limit: delivering stable, efficient, and resilient power at scale. Power instability hurts performance, reliability, hardware life, and operational efficiency.
To meet these challenges, the industry must adopt a holistic approach. This should integrate advanced power delivery architectures, real-time adaptive control, and system-level optimisation. The evolution of AI infrastructure will depend on the effective combination of these elements.
Here, power stability is not just a support; it is the main constraint. The future of AI depends less on speed or scale and more on the reliability of the energy sustaining it.
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Energy-Harvesting Micro-Power: The Future of Self-Powered IoT Devices How Ambient Energy is Eliminating Battery Replacements and Redefining Connected Electronics
The Internet of Things (IoT) is expected to connect tens of billions of devices over the coming decade. One of the most significant challenges facing this expansion is the power supply. Conventional batteries increase maintenance costs, create environmental waste, limit device lifetimes, and become impractical in large-scale deployments. Energy-harvesting micro-power technologies are emerging as a transformative solution, enabling autonomous devices that derive energy from their surrounding environment. By harvesting radio-frequency signals, thermal gradients, mechanical vibrations, and ambient light, next-generation IoT nodes can operate for years—or potentially indefinitely—without battery replacement.
For electronics engineers, energy harvesting represents a convergence of ultra-low-power electronics, advanced materials, power management ICs, and wireless communication technologies.
A new generation of Energy-Harvesting Micro-Power Systems is poised to overcome this limitation. Instead of relying solely on batteries, these devices extract energy from their environment—capturing radio frequency (RF) signals, body heat, ambient light, and mechanical vibrations—to power sensors, processors, and wireless communication modules.
For electronics engineers, energy harvesting represents more than an incremental improvement. It is enabling the development of self-powered, maintenance-free IoT networks capable of operating for years without human intervention. As ultra-low-power electronics continue to mature, battery-free devices are expected to become a cornerstone of Industry 4.0, smart cities, healthcare wearables, and environmental monitoring systems.
Energy harvesting is moving IoT design away from the “battery-first” model toward ultra-low-power, maintenance-light nodes that capture energy from their surroundings. In practice, that means converting ambient light, RF energy, thermal gradients, vibration, or motion into usable electrical power, then storing and regulating it for a sensor, MCU, and radio burst. The result is a class of devices that can run where wiring is expensive or battery replacement is impractical.
For working electronics engineers, the key shift is not just the harvester itself; it is the full power chain. A successful design needs a harvester, an energy-storage element, cold-start circuitry, and a PMIC that can regulate tiny input power levels while protecting the load. Vendors also emphasize maximum power point tracking and ultra-low quiescent current because harvested power is often measured in microwatts or low milliwatts, not watts.
The most promising ambient sources map well to real deployment environments. RF harvesting is attractive for low-power tags and short-duty-cycle nodes because it can turn broadcast energy into a regulated supply, though received power is usually small and distance-dependent. Thermal harvesting uses temperature differences, including body heat or industrial heat gradients, and is a strong fit for wearables and machinery-adjacent sensors. Vibration and piezoelectric harvesting are natural choices for motors, pumps, rotating equipment, and transport assets.
Several companies are actively building this ecosystem. Silicon Labs positions its EFR32xG22E energy-harvesting family around battery-less operation and reference designs for solar-powered and RF-powered batteryless tags, aimed at asset tracking and similar use cases. EnOcean’s wireless sensors and switches harvest energy from motion, light, and temperature differences for maintenance-free building and industrial applications. Powercast focuses on RF energy harvesting for low microwatt and low milliwatt applications, including RFID and wearables.
Thermal and multi-source harvesting are also well covered by major component vendors. STMicroelectronics offers energy-harvesting and solar-charging ICs for ambient light or thermal differences, and its SPV1050 supports thermoelectric and PV harvesting with MPPT. e-peas describes product families for photovoltaic, thermal, RF, and vibration harvesting, with thermal and vibration sources explicitly sized for the microwatt-to-millwatt range. Texas Instruments has also published low-power harvesters for light, heat, and vibration sources, highlighting battery-free operation for sensor networks and wearables.
For engineers, the design challenge is usually energy budgeting, not RF protocol selection. The load profile must fit the harvested envelope: deep sleep for most of the time, brief wake-ups for sensing and transmitting, and enough storage to survive startup and energy gaps. In many cases, the “batteryless” node still includes a supercapacitor or thin-film storage element, but the maintenance burden drops sharply because the system no longer depends on periodic battery replacement.
Where this is headed is clear: battery-free or battery-minimal IoT nodes will first win in asset tracking, smart buildings, wearables, industrial condition monitoring, shelf labels, and distributed sensing, where installation and service costs dominate. The best near-term opportunities are not power-hungry always-on devices, but ultra-low-duty-cycle systems that can tolerate intermittent energy while still delivering useful telemetry. That is exactly the niche energy harvesting is becoming ready to fill.
Companies Leading Energy-Harvesting Micro-Power Innovation
e-peas: A pioneer in energy-harvesting PMICs. Key focus areas include: Solar harvesting, Thermal harvesting, Vibration harvesting, Battery-free IoT platforms. Their AEM-series PMICs are widely used in autonomous sensor nodes.
STMicroelectronics: Develops ultra-low-power microcontrollers and energy-management solutions for industrial IoT. Contributions include: STM32 ultra-low-power MCUs, Energy harvesting reference designs, and smart industrial sensing platforms.
Texas Instruments: Offers energy-harvesting power-management ICs and ultra-low-power processors. Applications include: Wireless sensing, Building automation, and smart metering.
Analog Devices: A leader in vibration energy harvesting. Products support: Predictive maintenance, Condition monitoring, Industrial automation
Wiliot: Known for battery-free Bluetooth tags powered by ambient radio-frequency energy. Applications include: Supply chain visibility, Retail tracking, Smart packaging. Their technology demonstrates practical, large-scale RF-powered IoT deployments.
Powercast: Specializes in wireless power transfer and RF energy harvesting. Solutions include: RF transmitters, Power receivers, Battery-free sensors. Used extensively in industrial and logistics applications.
EnOcean: A pioneer in self-powered wireless switches and building automation systems. Its products harvest energy from: Button presses, Indoor light, Temperature differences.
Schneider Electric: Integrates energy-harvesting sensors into smart-building and industrial-management systems. Focus areas include: Energy efficiency, Building automation, and Sustainable infrastructure.
The Road Ahead
The convergence of Energy harvesting, Ultra-low-power electronics, AI-enabled edge processing, and advanced semiconductor materials is creating a new class of autonomous devices.
Research laboratories are already developing systems capable of operating continuously on harvested microwatts while performing local machine learning inference. As semiconductor power consumption continues to decline, the vision of truly maintenance-free IoT networks becomes increasingly realistic.
For electronics engineers, the next decade will not simply be about designing lower-power products—it will be about designing products that generate their own power.
Conclusion
Energy-harvesting micro-power technology is rapidly becoming a foundational enabler of the next generation of IoT systems. As ultra-low-power electronics, advanced materials, and intelligent power-management architectures continue to mature, the vision of maintenance-free, battery-independent sensor networks is moving from research laboratories into commercial reality. For electronics engineers, mastery of energy harvesting, power optimization, and autonomous sensing architectures will be essential skills in the coming decade. The future IoT ecosystem will not merely communicate wirelessly—it will increasingly power itself from the energy already present in its environment.
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Defence Electronics Warfare Technologies: Designing the Next Generation of Smart Defence Systems
Courtesy DefTech Bharat & DefTech Con Knowledge Desk
Future wars will be won not only by superior weapons, but by superior sensing, networking, electronic dominance, and AI-driven decision-making across the electromagnetic spectrum.
The future battlefield will be defined not merely by firepower but by dominance of the electromagnetic spectrum. Across the world, military planners are investing heavily in electronic warfare (EW), artificial intelligence, software-defined systems, autonomous platforms, and resilient communications. For defence electronics engineers, this transformation presents an unprecedented opportunity to develop agile, intelligent, and rapidly deployable systems capable of operating in highly contested environments.
Recent military operations have demonstrated that information superiority and electronic dominance can determine mission success before the first kinetic strike is launched. The growing convergence of electronic warfare, advanced semiconductors, cognitive computing, and network-centric operations is reshaping how next-generation defence systems are designed.
The Electronic Battlefield Has Changed
Traditional electronic warfare systems were largely platform-centric, consisting of dedicated radar warning receivers, jammers, communication intercept systems, and electronic countermeasures operating independently. Today’s battlefield is radically different.
Modern EW is increasingly becoming a “system-of-systems” architecture where satellites, drones, radars, communication networks, command centers, and autonomous platforms work together as a unified electronic ecosystem.
This shift allows military forces to sense, decide, and act faster than their adversaries. The ability to identify a threat, process intelligence, distribute information, and launch a response within seconds has become a decisive advantage.
For design engineers, the challenge is no longer building standalone equipment but creating modular, networked systems capable of functioning as part of a larger digital battlespace.
Operation Sindoor: A Lesson in Modern Electronic Warfare
India’s Operation Sindoor demonstrated the growing importance of electronic warfare, intelligence fusion, and precision targeting in modern military operations.
While many operational details remain classified, publicly available assessments indicate that the operation reflected a high degree of integration between surveillance systems, communication networks, precision-guided weapons, and command-and-control architectures.
The success of such operations depends heavily on several electronic warfare capabilities:
- Real-time intelligence gathering
- Electronic support measures (ESM)
- Radar and communication signal monitoring
- Secure data networks
- Precision navigation and targeting
- Integrated command systems
The operation highlighted a critical reality of modern warfare: victory increasingly depends on controlling information and the electromagnetic spectrum.
Modern military forces are now investing heavily in systems that can detect enemy emissions, disrupt hostile communications, protect friendly networks, and maintain operational effectiveness even under electronic attack.
Gallium Nitride: The Foundation of Next-Generation RF Systems
One of the most significant advances in defence electronics is the adoption of Gallium Nitride (GaN) semiconductor technology.
Traditional radar and electronic warfare transmitters relied on traveling-wave tubes and other vacuum-tube technologies that required large cooling systems and bulky infrastructure.
For defence designers, this translates directly into reduced Size, Weight, Power, and Cost (SWaP-C).
Modern Active Electronically Scanned Array (AESA) radars, airborne jammers, counter-drone systems, and electronic attack platforms increasingly rely on GaN technology to achieve higher performance within smaller form factors.
The result is the ability to deploy powerful electronic warfare capabilities on tactical vehicles, unmanned systems, and even portable soldier-carried platforms.
Cognitive AI: The New EW Operator
Conventional electronic warfare systems depend on predefined threat libraries. However, modern adversaries employ agile waveforms, frequency hopping, low-probability-of-intercept communications, and adaptive radar systems.
To counter these threats, defence engineers are embedding artificial intelligence directly into EW platforms.
Once a signal is identified, the system can automatically generate optimal jamming, spoofing, or deception strategies without requiring human intervention.
The future electronic battlefield will increasingly be fought by autonomous systems capable of learning and adapting in real time.
Modular Open Systems Architecture (MOSA)
Another major trend transforming defence electronics is the adoption of Modular Open Systems Architecture (MOSA).
Historically, defence systems were highly customized and difficult to upgrade. Introducing a new capability often required extensive hardware redesign.
MOSA changes this paradigm by promoting standardized interfaces and plug-and-play architectures.
At the heart of this approach is the Software-Defined Radio (SDR).
This flexibility dramatically reduces lifecycle costs and accelerates technology refresh cycles.
As threats evolve faster than traditional procurement cycles, MOSA provides a practical path to continuous capability enhancement.
GNSS-Free Navigation: Operating When GPS Fails
One of the most important lessons from contemporary conflicts is the vulnerability of satellite navigation systems.
GPS jamming and spoofing have become routine tactics on modern battlefields.
As a result, defence designers are increasingly focusing on GNSS-independent navigation solutions.
Emerging systems combine:
- Inertial Navigation Systems (INS)
- Terrain contour matching
- Visual navigation
- RF beacon triangulation
- LTE and 5G positioning
- Sensor fusion algorithms
Artificial intelligence combines these inputs to maintain accurate positioning even when satellite signals are unavailable.
For autonomous systems, missiles, drones, and tactical vehicles, GNSS resilience is rapidly becoming a mission-critical capability.
AI-Driven SWaP-C Optimization
The pressure to reduce Size, Weight, Power, and Cost continues to influence every defence program.
Machine learning is now being used to optimize engineering trade-offs before physical prototypes are built.
AI-assisted design platforms can evaluate:
- RF chain performance
- Thermal management
- Antenna placement
- Power consumption
- Electromagnetic compatibility
- Structural constraints
Digital twin technology allows engineers to test thousands of virtual configurations, dramatically reducing development time and improving design quality.
The integration of AI into the design process is becoming as important as AI within the deployed system itself.
DefTech Bharat: Accelerating India’s Defence Innovation Ecosystem
As India’s defence technology ecosystem expands, industry platforms are playing a critical role in connecting innovators, manufacturers, startups, system integrators, armed forces, and policymakers.
DefTech Bharat is an innovation-led defence technology platform that brings together companies, engineers, startups, OEMs, and government stakeholders to showcase next-generation solutions across defence electronics, software, hardware, testing, telematics, AI, drones, quantum technologies, autonomous systems, and cyber defence. For innovators working on electronic warfare, secure communications, GaN-based RF hardware, modular SDR platforms, and GNSS-resilient navigation, it provides a timely venue to demonstrate technologies, exchange ideas, and build partnerships with the wider defence ecosystem. By combining exhibition, technical engagement, and B2B networking, DefTech Bharat positions itself as a launchpad for rapidly deployable, out-of-the-box defence solutions.
For innovators developing:
- Electronic warfare systems
- AI-enabled defence platforms
- Software-defined radios
- GaN-based RF solutions
- Counter-drone technologies
- Autonomous vehicles
- Secure communication systems
DefTech Bharat provides a valuable opportunity to demonstrate capabilities, interact with defence stakeholders, and explore collaborative development opportunities.
The platform enables technology providers to showcase working prototypes, advanced subsystems, and deployable solutions to government agencies, defence organizations, OEMs, and strategic partners.
As India pursues self-reliance in defence technologies under the Atmanirbhar Bharat initiative, such platforms serve as catalysts for innovation, commercialization, and technology transfer.
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Brain-Computer Interfaces (BCIs) & Neurotechnology: The Next Frontier in Electronics Engineering
The convergence of neuroscience, electronics, and artificial intelligence is driving one of the most transformative technological revolutions of the 21st century: Brain-Computer Interfaces (BCIs) and neurotechnology. Once confined to science fiction, BCIs are now rapidly evolving into practical systems capable of enabling direct communication between the human brain and external electronic devices. For electronics engineers, this emerging domain offers exciting opportunities in embedded systems, signal processing, flexible electronics, biomedical instrumentation, and AI-driven hardware development.
The Rise of Brain-Computer Interfaces
A Brain-Computer Interface is a system that acquires neural signals, processes them, and translates them into commands for computers, prosthetics, or other electronic systems. Traditional BCIs relied on electroencephalography (EEG), where electrodes placed on the scalp measure brainwave activity. While non-invasive EEG systems remain important for research and healthcare applications, recent advances in high-density electrode arrays and implantable bioelectronics are dramatically improving signal quality and functionality.
Modern BCIs can now interpret neural activity with remarkable precision, enabling paralyzed individuals to control robotic limbs, type text using thought alone, and even regain limited speech capabilities. The integration of machine learning algorithms with neural signal acquisition hardware has accelerated these developments significantly.

Flexible Bioelectronics: A Game Changer
One of the biggest engineering challenges in neurotechnology has been the mechanical mismatch between rigid electronic devices and soft biological tissues. Conventional silicon-based implants often trigger inflammation or degrade over time due to tissue damage. Flexible bioelectronics are solving this issue.
Flexible neural interfaces are built using biocompatible materials such as polyimide, graphene, conductive polymers, and ultra-thin gold traces. These devices can bend and stretch with brain tissue, reducing long-term damage and improving signal stability. Engineers are also exploring bioresorbable electronics that safely dissolve in the body after completing their function.
For electronics engineers, flexible electronics require innovation in several areas:
- Low-power integrated circuit design
- Stretchable conductive materials
- Miniaturized sensor architectures
- Wireless power transfer systems
- High-speed neural signal amplification
These systems must operate reliably while consuming extremely low power to minimize heat generation near sensitive neural tissue.
High-Density Electrode Arrays and Neural Mapping
High-density electrode arrays are enabling researchers to record thousands of neurons simultaneously. Companies and research institutions are developing microelectrode arrays with unprecedented spatial resolution, allowing detailed mapping of neural activity patterns.
Advanced semiconductor fabrication techniques are making it possible to integrate thousands of microscopic electrodes onto a single chip. These arrays are combined with custom ASICs (Application-Specific Integrated Circuits) for signal amplification, filtering, analog-to-digital conversion, and wireless communication.
The data bandwidth generated by these systems is enormous. A next-generation BCI may process gigabits of neural data every second, creating major opportunities for engineers specializing in:
- Edge AI processing
- FPGA-based neural computing
- Real-time DSP systems
- Wireless telemetry
- Neuromorphic processors
Neuromorphic engineering, inspired by the architecture of the human brain, is becoming particularly important for efficient neural data processing. Unlike conventional processors, neuromorphic chips mimic biological neural networks and consume significantly less power.
Applications Transforming Healthcare
Healthcare remains the most promising application area for BCIs and neurotechnology. Neuroprosthetics are helping amputees control robotic limbs using brain signals with increasing accuracy and natural movement. Cochlear implants and retinal prostheses are restoring sensory functions to patients with hearing and vision impairments.
In neurological diagnostics, implantable neural sensors can monitor epilepsy, Parkinson’s disease, and other disorders in real time. Closed-loop neurostimulation systems can detect abnormal brain activity and automatically deliver corrective electrical stimulation.
Researchers are also investigating memory enhancement, depression treatment, and cognitive rehabilitation through targeted neural stimulation. These advancements depend heavily on reliable biomedical electronics and ultra-low-noise analog front-end design.

Patient controlling robotic prosthetic arm using BCI technology
Challenges and Ethical Considerations
Despite rapid progress, significant challenges remain. Neural signals are extremely weak and susceptible to noise, requiring sophisticated filtering and signal conditioning techniques. Long-term implant reliability, cybersecurity, and wireless communication safety are also major concerns.
Ethical issues surrounding cognitive enhancement, neural privacy, and brain data ownership are becoming increasingly important. As BCIs evolve from medical devices to consumer technologies, electronics engineers will play a critical role in designing secure and responsible systems.
Power management is another key challenge. Implantable devices require efficient energy harvesting or wireless charging technologies to avoid repeated surgical battery replacement. Advances in ultra-low-power electronics and energy-efficient communication protocols will be essential.
The Future of Neurotechnology
The future of BCIs lies in seamless human-machine integration. Emerging systems may eventually enable direct brain-to-brain communication, immersive virtual reality control, and advanced cognitive augmentation. Artificial intelligence combined with adaptive neural interfaces could create highly personalized neuroprosthetic systems capable of learning and evolving with users.
For electronics engineers, neurotechnology represents a multidisciplinary field where expertise in electronics, embedded systems, materials science, AI, and biomedical engineering converge. As the boundaries between biology and electronics continue to blur, BCIs are poised to become one of the defining technologies of the coming decades.
The era of intelligent bioelectronic systems has begun — and electronics engineers are at the center of this technological transformation.
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