Significant leap with development of indigenous post-quantum cryptography applications, says Army
The
Indian Army
on Friday said it has taken a "significant leap" in harnessing quantum technologies with the development of indigenous
post-quantum cryptography
applications, a move that aims to bolster its capabilities across domains and to ensure the force remains future ready in "ever-evolving technological landscape".
In a post on X, ADG PI - Indian Army also shared some photos along with a caption titled - "Enabling the Battlefield of Tomorrow with Quantum Tech".
The Indian Army had declared 2024 as the '
Year of Technology Absorption
' and is undertaking various initiatives to induct niche technology and systems into its inventory.
Sponsored Links
Sponsored Links
Promoted Links
Promoted Links
You May Like
Elegant New Scooters For Seniors In 2024: The Prices May Surprise You
Mobility Scooter | Search Ads
Learn More
by Taboola
by Taboola
"The Indian Army takes a significant leap in harnessing Quantum Technologies with the development of indigenous Post-Quantum Cryptography (PQC) applications," it posted.
These applications have been developed by the
Military College of Telecommunication Engineering
(MCTE), Mhow, under the aegis of the Corps of Signals and in alignment with the technology research vision of the Chief of the Army Staff, the post read.
Live Events
"Post-Quantum Cryptography based solutions are being progressively integrated across Army networks - strengthening capabilities across domains and ensuring Indian Army remains future ready in ever evolving technological landscape. #Atmanirbharta #YearofTechAbsorption #DecadeofTransformation @DefenceMinIndia @SpokespersonMoD @HQ_IDS_India," it posted.
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Time of India
38 minutes ago
- Time of India
Japan discovers game-changing metal that boosts Hydrogen output by 1,000%—world closer to fossil-free future
Japan has revealed an effective way to move toward a green future, as researchers at the RIKEN Institute have a new way of producing green hydrogen, as per a report. A New Hope for Green Hydrogen While countries like Spain are producing green hydrogen by using renewable energy sources to do electrolysis of water, Japan has found a way to produce the green energy on a sustainable scale, as per the Farmingdale report. Recently, the most popular way of producing hydrogen is via PEM electrolysers, which use a proton exchange membrane as the electrolyte, due to its greater efficiency and ability to respond rapidly to intermittent energy sources, according to the Farmingdale report. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like The Simple Morning Habit for a Flatter Belly After 50! Lulutox Undo ALSO READ: No Kings protest takes toll: Trump's approval rating hits -6, marking sharpest drop in months The PEM Electrolyser Problem However, it's not a sustainable model because PEM electrolysers are very expensive and also require efficient catalysts that can resist corrosion in acid and therefore use platinum or iridium, which are rare and expensive metals, reported Farmingdale. It is used because iridium catalysts can prolong the oxygen conversion reaction and produce huge quantities of hydrogen, as per the report. Live Events Japan's Game-Changing Discovery But now, researchers at Japan's RIKEN Institute discovered that there is a cheap material which is capable of doing the same thing, according to the report. Japanese researchers studied and used a common metal, manganese, and modified its three-dimensional structure to create the first efficient and sustainable PEM electrolyser without rare metals, as per the Farmingdale report. According to the report, the researchers developed a manganese oxide (MnO2) catalyst by manipulating the lattice structure of the material to form stronger bonds with oxygen atoms. This improved MnO2 is even more stable than any other non-noble metal catalysts and even maintains the reaction with water for much longer, generating 1,000% more hydrogen, reported Farmingdale. As per a study published in Nature Catalysis, MnO2 can increase the lifespan of other cheap catalysts by a factor of 40, reported Farmingdale. The researchers found that this material is more resistant to dissolution in acid and is also more stable during the reaction, Farmingdale. During the laboratory tests, the researchers found that the catalyst operated for more than 1,000 hours at 200 mA/cm² and produced 10 times more hydrogen than any other materials, as per Farmingdale. Farmingdale wrote, "Future modifications to the manganese structure could further increase the current density supported by the material and the lifetime of the catalyst, with the long-term aim of making water electrolysis iridium-free." FAQs What did Japanese scientists discover? They found a way to use manganese, a cheap and common metal, to replace expensive rare metals in hydrogen production, which will make the process more affordable and sustainable, as per the Farmingdale report. Why is this important? Because green hydrogen could be a key part of a fossil-free energy future, and Japan's discovery could help make it widely accessible.
Time of India
40 minutes ago
- Time of India
EU launches radical smartphone labels to expose flaws and features — here's what you need to know
EU smartphone energy labels now mandatory: what buyers need to know before purchasing new devices- Starting June 20, 2025, all new smartphones and tablets sold in the EU must now include an official energy efficiency label inside their packaging. This is part of a sweeping new regulation from the European Commission, aimed at making the tech industry more transparent and sustainable. Just like refrigerators or washing machines, mobile devices will now come with a clear ENERGY label, giving users key information about durability, battery life, and repairability. For millions of users across Europe, this marks a major shift in how we compare and shop for phones and tablets. What does the new EU smartphone energy label actually show? The new EU energy label for smartphones includes seven key pieces of information to help consumers make smarter, greener choices: Energy efficiency class: Rated from A (most efficient) to G (least efficient). Play Video Pause Skip Backward Skip Forward Unmute Current Time 0:00 / Duration 0:00 Loaded : 0.00% 0:00 Stream Type LIVE Seek to live, currently behind live LIVE Remaining Time - 0:00 1x Playback Rate Chapters Chapters Descriptions descriptions off , selected Captions captions settings , opens captions settings dialog captions off , selected Audio Track default , selected Picture-in-Picture Fullscreen This is a modal window. Beginning of dialog window. Escape will cancel and close the window. Text Color White Black Red Green Blue Yellow Magenta Cyan Opacity Opaque Semi-Transparent Text Background Color Black White Red Green Blue Yellow Magenta Cyan Opacity Opaque Semi-Transparent Transparent Caption Area Background Color Black White Red Green Blue Yellow Magenta Cyan Opacity Transparent Semi-Transparent Opaque Font Size 50% 75% 100% 125% 150% 175% 200% 300% 400% Text Edge Style None Raised Depressed Uniform Drop shadow Font Family Proportional Sans-Serif Monospace Sans-Serif Proportional Serif Monospace Serif Casual Script Small Caps Reset restore all settings to the default values Done Close Modal Dialog End of dialog window. Battery endurance per charge: Shows how long a phone lasts on a full battery. Drop test durability: A rating from A to E based on repeated free-fall tests. Battery life cycle: Number of full charge-discharge cycles it can handle. Repairability rating: A to E scale showing how easy the device is to repair. Ingress protection (IP rating): Resistance to dust and water. Product registration: All details are stored in the EPREL (European Product Registry for Energy Labelling). This helps users understand how long the phone will last, how tough it is, and how eco-friendly its design is—before they even power it on. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like 開脚でゆがみを整えてまっすぐな体へ! amepla 詳細 Undo Which phones and tablets are affected by the EU energy label rule? This rule applies to a wide range of devices sold in the EU/EEA market: Smartphones (on cellular or satellite networks) Tablets with screens between 7 and 17.4 inches Cordless landline phones Feature phones (without internet or third-party apps) However, there are some notable exceptions: Live Events Devices released before June 20, 2025 Phones with rollable displays High-security smartphones (for government or defense use) Tablets with full-featured desktop OS (like Windows 10/11 Pro) These exceptions will not carry the new label. What are the new eco-design rules that every phone must follow? Beyond just the label, every new smartphone and tablet must now meet five mandatory eco-design standards: Durability: Must survive accidental drops and meet dust/water resistance standards. Battery longevity: Batteries need to last at least 800 full cycles and still retain 80% of their original capacity. Repairability: Brands must offer spare parts within 5–10 working days, for at least 7 years after the device is off shelves. Software support: Operating system updates are now required for 5 years from end-of-sale date. Repair access: Independent repair shops must get equal access to software tools and firmware. These rules push smartphone brands to build longer-lasting, more sustainable devices—and make it easier for people to fix their phones instead of replacing them. How is battery life measured under this new EU regulation? One interesting detail is that the battery endurance rating in the new labels is tested using the same software used by many tech reviewers: SmartViser. This French automation company works with labs and manufacturers to simulate real-world usage. So now, the battery performance you see on the label is based on consistent, lab-tested data, not just marketing claims. That means when you see a phone rated for 15 hours per charge, you can trust it's been tested in a fair, comparable way across brands. What does this mean for consumers and the smartphone industry? For shoppers in Europe, this label makes it easier than ever to compare phones based on more than just camera specs or price. It gives visibility into how sustainable and durable a device is, and whether it will be supported and repairable for years to come. For manufacturers, it's a strong push toward eco-friendly product design, longer software support, and better repair practices. And for the environment, this move aims to cut down on electronic waste and reduce CO₂ emissions across the continent. This could even influence markets beyond Europe, as global smartphone brands are now designing their devices to comply with these new EU rules. A new era of smartphone transparency This energy labelling law marks a major step forward for consumer rights and environmental responsibility in the mobile industry. With clearer data, better standards, and more durable devices, the EU is setting a bold example for the rest of the world. So the next time you pick up a new phone in an EU store, take a good look at that ENERGY label—it could save you money, time, and help the planet, all at once. FAQs: Q1: What is the EU smartphone energy label and why is it important? The EU smartphone energy label shows how energy efficient, durable, and repairable a phone is before you buy it. Q2: Which devices need the EU energy label from June 2025? All new smartphones and tablets sold in the EU must include this energy label, except for a few special-use or older devices.
Time of India
an hour ago
- Time of India
Algebra, philosophy and…: These AI chatbot queries cause most harm to environment, study claims
Representative Image Queries demanding complex reasoning from AI chatbots, such as those related to abstract algebra or philosophy, generate significantly more carbon emissions than simpler questions, a new study reveals. These high-level computational tasks can produce up to six times more emissions than straightforward inquiries like basic history questions. A study conducted by researchers at Germany's Hochschule München University of Applied Sciences, published in the journal Frontiers (seen by The Independent), found that the energy consumption and subsequent carbon dioxide emissions of large language models (LLMs) like OpenAI's ChatGPT vary based on the chatbot, user, and subject matter. An analysis of 14 different AI models consistently showed that questions requiring extensive logical thought and reasoning led to higher emissions. To mitigate their environmental impact, the researchers have advised frequent users of AI chatbots to consider adjusting the complexity of their queries. Why do these queries cause more carbon emissions by AI chatbots In the study, author Maximilian Dauner wrote: 'The environmental impact of questioning trained LLMs is strongly determined by their reasoning approach, with explicit reasoning processes significantly driving up energy consumption and carbon emissions. We found that reasoning-enabled models produced up to 50 times more carbon dioxide emissions than concise response models.' by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like Americans Are Freaking Out Over This All-New Hyundai Tucson (Take a Look) Smartfinancetips Learn More Undo The study evaluated 14 large language models (LLMs) using 1,000 standardised questions to compare their carbon emissions. It explains that AI chatbots generate emissions through processes like converting user queries into numerical data. On average, reasoning models produce 543.5 tokens per question, significantly more than concise models, which use only 40 tokens. 'A higher token footprint always means higher CO2 emissions,' the study adds. The study highlights that Cogito, one of the most accurate models with around 85% accuracy, generates three times more carbon emissions than other similarly sized models that offer concise responses. 'Currently, we see a clear accuracy-sustainability trade-off inherent in LLM technologies. None of the models that kept emissions below 500 grams of carbon dioxide equivalent achieved higher than 80 per cent accuracy on answering the 1,000 questions correctly,' Dauner explained. Researchers used carbon dioxide equivalent to measure the climate impact of AI models and hope that their findings encourage more informed usage. For example, answering 600,000 questions with DeepSeek R1 can emit as much carbon as a round-trip flight from London to New York. In comparison, Alibaba Cloud's Qwen 2.5 can answer over three times more questions with similar accuracy while producing the same emissions. 'Users can significantly reduce emissions by prompting AI to generate concise answers or limiting the use of high-capacity models to tasks that genuinely require that power,' Dauner noted. AI Masterclass for Students. Upskill Young Ones Today!– Join Now
