Galaxy S26 Ultra camera:
main camera 200MP F1.4
ultra-wide 50mp F1.9
3x 12mp F2.4
5x 50MP F2.9
main camera 200MP F1.4
ultra-wide 50mp F1.9
3x 12mp F2.4
5x 50MP F2.9
😭8❤1
https://youtu.be/RTgHrY1gZlM
https://youtu.be/RTgHrY1gZlM
https://youtu.be/RTgHrY1gZlM
Link x Link x Link x Link
All links are same; use anyone
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❤3
Next week in tech -
1. #AppleEvent - iPhone 17, iPhone 17 Air, iPhone 17 Pro series
2. Amazon Great Indian Festival and Flipkart Big Billion Days Sale deals reveal (partial)
3. OnePlus Nord Buds 3r to go on sale
1. #AppleEvent - iPhone 17, iPhone 17 Air, iPhone 17 Pro series
2. Amazon Great Indian Festival and Flipkart Big Billion Days Sale deals reveal (partial)
3. OnePlus Nord Buds 3r to go on sale
From 15 Sep 2025, NPCI raises UPI limits for merchant/shop payments (not person-to-person):
• Most merchants: ₹5 lakh per transaction — ₹10 lakh/day
• Credit-card bill payments via UPI: ₹5 lakh per transaction — ₹6 lakh/day
• Jewellery shops: ₹2 lakh per transaction — ₹6 lakh/day
Banks may still apply lower per-transaction or daily caps.
• Most merchants: ₹5 lakh per transaction — ₹10 lakh/day
• Credit-card bill payments via UPI: ₹5 lakh per transaction — ₹6 lakh/day
• Jewellery shops: ₹2 lakh per transaction — ₹6 lakh/day
Banks may still apply lower per-transaction or daily caps.
The 3X telephoto on the OPPO Find X9 Ultra is said to be the same size as S26 Ultra/iPhone 17 Pro’s main camera
LYT-828 1/1.28” 3X
It will also feature a 6X-8X Samsung HP5 1/1.56” for long zoom
LYT-828 1/1.28” 3X
It will also feature a 6X-8X Samsung HP5 1/1.56” for long zoom
❤1
https://youtu.be/YwuxFMg2tIk
https://youtu.be/YwuxFMg2tIk
https://youtu.be/YwuxFMg2tIk
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Recover deleted photos!
It’s easy trick to recover
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Tech Office : Updates & Tech News ~1
Photo
Why Older Chips Fly: A Global Look at Space Mission Processors
For multi-billion dollar space missions where repair is impossible, reliability and radiation-hardening are paramount, far outweighing the need for cutting-edge speed. The harsh radiation of space can disrupt modern, delicate chips. This is why proven, robust, and often "older" processor technologies are the global standard for the most critical missions.
---
🚀 NASA (USA)
NASA consistently uses trusted, mature technology for its flagship assets.
* Perseverance Rover & James Webb Telescope: Both rely on processors built with 150nm to 250nm technology for extreme reliability and radiation resistance.
* Artemis Program: The Orion spacecraft, designed to carry astronauts to the Moon, uses a 130nm processor for its core flight computer.
* Ingenuity Helicopter: As a non-mission-critical *technology demonstrator*, it used a commercial 28nm Snapdragon chip to test how modern hardware survives on Mars.
🇪🇺 ESA (European Space Agency)
ESA also trusts flight-proven technology for its long-duration and complex missions.
* JUICE Mission (to Jupiter): Uses a 180nm CMOS processor for its primary systems.
* PROBA-3 Mission: Employs a 65nm CMOS processor, a technology with a strong record of success in space ("flight heritage") since 2005.
🇷🇺 Roscosmos (Russia) & 🇨🇳 CNSA (China)
Other global powers follow a similar strategy, prioritizing reliability.
* Roscosmos: Russia's most critical systems, like the Soyuz spacecraft and Luna landers, primarily use processors in the 65nm to 180nm range.
* CNSA: China employs a mixed approach. It uses trusted 180nm tech for core systems like its Beidou navigation satellites, while testing newer 16nm to 65nm chips on other missions to build confidence for future use.
🛰️ SpaceX
SpaceX uses an innovative software-based approach called Triple Modular Redundancy.
* Instead of one expensive, radiation-hardened chip, the Falcon 9 rocket uses three commercial, off-the-shelf x86 dual-core processors.
* A critical calculation is performed on all three simultaneously. A command is only executed if at least two processors agree on the result, effectively outvoting any radiation-induced errors.
---
Final Verdict: Why ISRO's VIKRAM 32 is a Major Achievement
The development of the VIKRAM 32 processor on 180nm technology is a significant and strategic success for India, not a sign of being behind.
1. It's a Strategic Choice for Reliability:
This technology aligns perfectly with the global standard for mission-critical space hardware, where robustness against the harsh environment of space is the top priority.
2. A Foundational Step for Self-Reliance:
By mastering this process, ISRO has built a crucial capability for its self-reliance goals. It is a vital achievement that paves the way for India to develop even more advanced and reliable space-grade processors in the future.
For multi-billion dollar space missions where repair is impossible, reliability and radiation-hardening are paramount, far outweighing the need for cutting-edge speed. The harsh radiation of space can disrupt modern, delicate chips. This is why proven, robust, and often "older" processor technologies are the global standard for the most critical missions.
---
🚀 NASA (USA)
NASA consistently uses trusted, mature technology for its flagship assets.
* Perseverance Rover & James Webb Telescope: Both rely on processors built with 150nm to 250nm technology for extreme reliability and radiation resistance.
* Artemis Program: The Orion spacecraft, designed to carry astronauts to the Moon, uses a 130nm processor for its core flight computer.
* Ingenuity Helicopter: As a non-mission-critical *technology demonstrator*, it used a commercial 28nm Snapdragon chip to test how modern hardware survives on Mars.
🇪🇺 ESA (European Space Agency)
ESA also trusts flight-proven technology for its long-duration and complex missions.
* JUICE Mission (to Jupiter): Uses a 180nm CMOS processor for its primary systems.
* PROBA-3 Mission: Employs a 65nm CMOS processor, a technology with a strong record of success in space ("flight heritage") since 2005.
🇷🇺 Roscosmos (Russia) & 🇨🇳 CNSA (China)
Other global powers follow a similar strategy, prioritizing reliability.
* Roscosmos: Russia's most critical systems, like the Soyuz spacecraft and Luna landers, primarily use processors in the 65nm to 180nm range.
* CNSA: China employs a mixed approach. It uses trusted 180nm tech for core systems like its Beidou navigation satellites, while testing newer 16nm to 65nm chips on other missions to build confidence for future use.
🛰️ SpaceX
SpaceX uses an innovative software-based approach called Triple Modular Redundancy.
* Instead of one expensive, radiation-hardened chip, the Falcon 9 rocket uses three commercial, off-the-shelf x86 dual-core processors.
* A critical calculation is performed on all three simultaneously. A command is only executed if at least two processors agree on the result, effectively outvoting any radiation-induced errors.
---
Final Verdict: Why ISRO's VIKRAM 32 is a Major Achievement
The development of the VIKRAM 32 processor on 180nm technology is a significant and strategic success for India, not a sign of being behind.
1. It's a Strategic Choice for Reliability:
This technology aligns perfectly with the global standard for mission-critical space hardware, where robustness against the harsh environment of space is the top priority.
2. A Foundational Step for Self-Reliance:
By mastering this process, ISRO has built a crucial capability for its self-reliance goals. It is a vital achievement that paves the way for India to develop even more advanced and reliable space-grade processors in the future.
❤2