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riya2510 · 6 months ago

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The Industrial IoT Revolution: Market Forecast and Leading Players to Watch in 2023–2031

Industrial IoT Market Report: Growth, Trends, and Future Outlook

The Industrial Internet of Things (IIoT) represents a transformative wave in industrial operations, leveraging the power of connected devices, sensors, and advanced analytics to optimize processes, improve efficiency, and unlock new business opportunities. IIoT connects machines, devices, sensors, and systems to collect and analyze data in real time, enabling industries to achieve smarter decision-making, reduce operational costs, and enhance productivity.

The global Industrial IoT (IIoT) market was valued at USD 334.53 billion in 2022 and is projected to reach USD 2,916.21 billion by 2031, growing at an impressive CAGR of 27.2% during the forecast period (2023–2031). This rapid growth highlights the increasing demand for IoT-enabled technologies across various industrial sectors, making IIoT a vital part of the digital transformation process in manufacturing, supply chains, and infrastructure.

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Key Trends in the Industrial IoT Market

Increased Adoption of Smart Manufacturing: Manufacturers are embracing IIoT for process automation, predictive maintenance, real-time monitoring, and supply chain optimization. This trend is expected to continue as more companies focus on reducing downtime and improving product quality through connected devices.

Advancements in Edge Computing and AI Integration: The rise of edge computing is reducing latency, enabling faster data processing at the source. Integrating AI and machine learning with IIoT systems allows industries to gain insights from real-time data, improving decision-making capabilities.

Focus on Cybersecurity: As the number of connected devices increases, so does the potential vulnerability to cyberattacks. Ensuring robust cybersecurity measures within IIoT systems is becoming a top priority for businesses.

5G Connectivity: The rollout of 5G technology is enhancing the capabilities of IIoT by offering faster and more reliable communication between connected devices. This enables applications that require low latency, such as autonomous vehicles and real-time remote monitoring.

Sustainability and Energy Efficiency: Industries are increasingly adopting IIoT technologies to improve energy efficiency, reduce emissions, and support sustainability goals. Sensors and data analytics enable more efficient resource management, leading to reduced waste and energy consumption.

Industrial IoT Market Size and Share

The IIoT market is witnessing substantial growth across various regions, driven by technological advancements, an increasing number of connected devices, and the need for automation. The major industrial sectors benefiting from IIoT include manufacturing, energy, automotive, pharmaceuticals, and more. Businesses are investing heavily in IIoT to streamline their operations, reduce operational costs, and ensure more efficient use of resources.

The market is also being driven by increasing government initiatives aimed at fostering smart city projects, digital infrastructure, and sustainable industrial practices. As industries continue to digitize their operations, the demand for IIoT solutions is poised to grow exponentially.

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Industrial IoT Market Statistics

The global market value was USD 334.53 billion in 2022.

The market is expected to grow to USD 2,916.21 billion by 2031, with a CAGR of 27.2% during the forecast period (2023–2031).

North America holds a significant share of the market, driven by the adoption of advanced industrial technologies and the presence of key players like Cisco, IBM, and Honeywell.

Asia Pacific (APAC) is expected to witness the highest growth due to rapid industrialization, increasing investments in smart factories, and government support for smart manufacturing initiatives.

Regional Trends and Impact

North America: The North American region, particularly the United States and Canada, dominates the global IIoT market due to a robust manufacturing base, the presence of key technology companies, and early adoption of IoT-enabled technologies. The region’s focus on automation, smart factories, and energy efficiency has led to a high demand for IIoT solutions.

Asia Pacific (APAC): APAC is expected to witness the fastest growth in the IIoT market, primarily driven by the increasing industrialization in countries like China, Japan, and India. The region's push towards smart manufacturing, government initiatives supporting industrial automation, and rapid adoption of advanced technologies like AI, robotics, and 5G are propelling the growth of the IIoT market.

Europe: Europe is another key region for IIoT, driven by strong industrial sectors such as automotive, chemicals, and energy. The European Union’s focus on Industry 4.0 and digital transformation is increasing the demand for IIoT technologies across manufacturing, energy, and logistics.

LAMEA (Latin America, Middle East, and Africa): While still a developing market, the LAMEA region is showing significant potential for IIoT growth, especially in industries such as oil and gas, utilities, and agriculture. Increased investment in infrastructure and digitalization is expected to drive the demand for IIoT solutions in these regions.

Industrial IoT Market Segmentation

By Offering

Hardware:

Industrial Robots: These robots are essential for automating repetitive tasks in industries such as manufacturing and automotive, improving efficiency and reducing errors.

Industrial PC: Industrial PCs are used for data processing, monitoring, and control in industrial environments.

Industrial Sensors: Sensors play a critical role in collecting data from machines and devices to monitor conditions like temperature, pressure, and vibration.

Distributed Control System (DCS): DCS solutions enable centralized control of industrial processes, helping manage large-scale production systems.

Smart Meters: Smart meters are essential for monitoring and managing energy consumption in industries, contributing to energy efficiency.

Human Machine Interface (HMI): HMIs provide a visual interface for operators to interact with industrial control systems.

Control Devices: Devices that help regulate and control industrial processes, ensuring smooth operations.

Software: Software solutions in IIoT are used for data collection, processing, analytics, and visualization. These software tools enable industries to derive actionable insights from the vast amount of data generated by IIoT devices.

Services:

Training & Consulting Services: These services help organizations integrate IIoT technologies into their existing systems and operations.

Support and Maintenance Services: These services ensure that IIoT solutions continue to operate efficiently and without disruption.

By Connectivity

Wired Connectivity:

Ethernet: Provides high-speed, reliable data transmission for industrial applications.

Fieldbus: Used in process control systems for connecting field devices and control systems.

Wireless Connectivity:

Wi-Fi, Bluetooth, Cellular Connectivity, Satellite Connectivity: Wireless connectivity solutions offer flexibility and scalability for IIoT applications, especially in large industrial environments.

By End-use Industry

Aerospace and Defense

Automotive

Chemicals

Energy & Power

Food & Beverage

Metal and Mining

Oil & Gas

Pharmaceutical

Semiconductor & Electronics

Others (Healthcare, Water & Wastewater, etc.)

Each of these industries is increasingly adopting IIoT technologies to improve operational efficiency, ensure product quality, reduce costs, and enhance safety.

Market Segmentation with Insights-Driven Strategy Guide: https://straitsresearch.com/report/industrial-iot-market/segmentation

Top Players in the Industrial IoT Market

Several companies are leading the way in the IIoT market, providing innovative solutions and services:

Huawei Technology Co., Ltd.

Cisco

General Electric

Schneider Electric

Rockwell Automation

ABB

Texas Instruments

Honeywell

IBM

KUKA AG

NEC Corporation

Bosch

Siemens AG

SAP

Endress+Hauser

Accenture PLC

STMicroelectronics

These companies are at the forefront of developing and implementing IIoT solutions, helping industries to leverage IoT technologies for better efficiency, safety, and profitability.

Table of Contents for the Industrial IoT Market Report: https://straitsresearch.com/report/industrial-iot-market/toc

Conclusion

The Industrial IoT market is experiencing rapid growth as industries worldwide adopt connected devices, advanced analytics, and automation to enhance productivity, reduce costs, and improve decision-making. With significant investments in IIoT infrastructure, the market is poised to expand substantially in the coming years, especially in sectors such as manufacturing, energy, automotive, and pharmaceuticals. As technologies like AI, 5G, and edge computing continue to evolve, the potential for IIoT to drive industrial transformation will only increase, presenting enormous opportunities for businesses and industries to embrace the future of connected manufacturing and operations.

About Straits Research

Straits Research is a leading provider of market research and intelligence services. With a focus on high-quality research, analytics, and advisory, our team offers actionable insights tailored to clients’ strategic needs.

Contact Us Email: [email protected] Address: 825 3rd Avenue, New York, NY, USA, 10022 Tel: UK: +44 203 695 0070, USA: +1 646 905 0080

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automationexperts · 1 year ago

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Unveiling the Power of Vibration Sensor

Two Switching Outputs

Employs pre-alarm and main alarm outputs for enhanced monitoring and response.

Integrated History Memory with Real-Time Clock

Facilitates seamless data monitoring, display, and recording, bolstering operational efficiency.

Scalable Analogue Current Output

Delivers precise measurements of vibration velocity, optimizing performance analysis.

Versatile Analogue Input

Enables monitoring of additional measurements, expanding its utility beyond vibration detection.

A Multifaceted Guardian

Comprehensive Insights

Provides deep insights into machinery performance and environmental conditions.

Proactive Maintenance

Alerts to potential issues before they escalate, ensuring preemptive actions.

Adaptability Across Industries

Reliable tool for diverse sectors, ensuring optimal functioning and strategic maintenance.

Conclusion: Empowering Proactive Decision-Making

The vibration sensor emerges as a cornerstone in monitoring and control, empowering proactive decision-making and safeguarding critical systems. Its advanced features and adaptability make it indispensable across industries, ensuring optimal performance and preemptive maintenance

#Vibration Sensor #Vibration Sensor automation #Vibration Sensor for industrial agricaltural use #Vibration Sensor for factory #Vibration Sensor india #Vibration Sensor buy online

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usafphantom2 · 11 months ago

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B-2 Gets Big Upgrade with New Open Mission Systems Capability

July 18, 2024 | By John A. Tirpak

The B-2 Spirit stealth bomber has been upgraded with a new open missions systems (OMS) software capability and other improvements to keep it relevant and credible until it’s succeeded by the B-21 Raider, Northrop Grumman announced. The changes accelerate the rate at which new weapons can be added to the B-2; allow it to accept constant software updates, and adapt it to changing conditions.

“The B-2 program recently achieved a major milestone by providing the bomber with its first fieldable, agile integrated functional capability called Spirit Realm 1 (SR 1),” the company said in a release. It announced the upgrade going operational on July 17, the 35th anniversary of the B-2’s first flight.

SR 1 was developed inside the Spirit Realm software factory codeveloped by the Air Force and Northrop to facilitate software improvements for the B-2. “Open mission systems” means that the aircraft has a non-proprietary software architecture that simplifies software refresh and enhances interoperability with other systems.

“SR 1 provides mission-critical capability upgrades to the communications and weapons systems via an open mission systems architecture, directly enhancing combat capability and allowing the fleet to initiate a new phase of agile software releases,” Northrop said in its release.

The system is intended to deliver problem-free software on the first go—but should they arise, correct software issues much earlier in the process.

The SR 1 was “fully developed inside the B-2 Spirit Realm software factory that was established through a partnership with Air Force Global Strike Command and the B-2 Systems Program Office,” Northrop said.

The Spirit Realm software factory came into being less than two years ago, with four goals: to reduce flight test risk and testing time through high-fidelity ground testing; to capture more data test points through targeted upgrades; to improve the B-2’s functional capabilities through more frequent, automated testing; and to facilitate more capability upgrades to the jet.

The Air Force said B-2 software updates which used to take two years can now be implemented in less than three months.

In addition to B61 or B83 nuclear weapons, the B-2 can carry a large number of precision-guided conventional munitions. However, the Air Force is preparing to introduce a slate of new weapons that will require near-constant target updates and the ability to integrate with USAF’s evolving long-range kill chain. A quicker process for integrating these new weapons with the B-2’s onboard communications, navigation, and sensor systems was needed.

The upgrade also includes improved displays, flight hardware and other enhancements to the B-2’s survivability, Northrop said.

“We are rapidly fielding capabilities with zero software defects through the software factory development ecosystem and further enhancing the B-2 fleet’s mission effectiveness,” said Jerry McBrearty, Northrop’s acting B-2 program manager.

The upgrade makes the B-2 the first legacy nuclear weapons platform “to utilize the Department of Defense’s DevSecOps [development, security, and operations] processes and digital toolsets,” it added.

The software factory approach accelerates adding new and future weapons to the stealth bomber, and thus improve deterrence, said Air Force Col. Frank Marino, senior materiel leader for the B-2.

The B-2 was not designed using digital methods—the way its younger stablemate, the B-21 Raider was—but the SR 1 leverages digital technology “to design, manage, build and test B-2 software more efficiently than ever before,” the company said.

The digital tools can also link with those developed for other legacy systems to accomplish “more rapid testing and fielding and help identify and fix potential risks earlier in the software development process.”

Following two crashes in recent years, the stealthy B-2 fleet comprises 19 aircraft, which are the only penetrating aircraft in the Air Force’s bomber fleet until the first B-21s are declared to have achieved initial operational capability at Ellsworth Air Force Base, S.D. A timeline for IOC has not been disclosed.

The B-2 is a stealthy, long-range, penetrating nuclear and conventional strike bomber. It is based on a flying wing design combining LO with high aerodynamic efficiency. The aircraft’s blended fuselage/wing holds two weapons bays capable of carrying nearly 60,000 lb in various combinations.

Spirit entered combat during Allied Force on March 24, 1999, striking Serbian targets. Production was completed in three blocks, and all aircraft were upgraded to Block 30 standard with AESA radar. Production was limited to 21 aircraft due to cost, and a single B-2 was subsequently lost in a crash at Andersen, Feb. 23, 2008.

Modernization is focused on safeguarding the B-2A’s penetrating strike capability in high-end threat environments and integrating advanced weapons.

The B-2 achieved a major milestone in 2022 with the integration of a Radar Aided Targeting System (RATS), enabling delivery of the modernized B61-12 precision-guided thermonuclear freefall weapon. RATS uses the aircraft’s radar to guide the weapon in GPS-denied conditions, while additional Flex Strike upgrades feed GPS data to weapons prerelease to thwart jamming. A B-2A successfully dropped an inert B61-12 using RATS on June 14, 2022, and successfully employed the longer-range JASSM-ER cruise missile in a test launch last December.

Ongoing upgrades include replacing the primary cockpit displays, the Adaptable Communications Suite (ACS) to provide Link 16-based jam-resistant in-flight retasking, advanced IFF, crash-survivable data recorders, and weapons integration. USAF is also working to enhance the fleet’s maintainability with LO signature improvements to coatings, materials, and radar-absorptive structures such as the radome and engine inlets/exhausts.

Two B-2s were damaged in separate landing accidents at Whiteman on Sept. 14, 2021, and Dec. 10, 2022, the latter prompting an indefinite fleetwide stand-down until May 18, 2023. USAF plans to retire the fleet once the B-21 Raider enters service in sufficient numbers around 2032.

Contractors: Northrop Grumman; Boeing; Vought.

First Flight: July 17, 1989.

Delivered: December 1993-December 1997.

IOC: April 1997, Whiteman AFB, Mo.

Production: 21.

Inventory: 20.

Operator: AFGSC, AFMC, ANG (associate).

Aircraft Location: Edwards AFB, Calif.; Whiteman AFB, Mo.

Active Variant: •B-2A. Production aircraft upgraded to Block 30 standards.

Dimensions: Span 172 ft, length 69 ft, height 17 ft.

Weight: Max T-O 336,500 lb.

Power Plant: Four GE Aviation F118-GE-100 turbofans, each 17,300 lb thrust.

Performance: Speed high subsonic, range 6,900 miles (further with air refueling).

Ceiling: 50,000 ft.

Armament: Nuclear: 16 B61-7, B61-12, B83, or eight B61-11 bombs (on rotary launchers). Conventional: 80 Mk 62 (500-lb) sea mines, 80 Mk 82 (500-lb) bombs, 80 GBU-38 JDAMs, or 34 CBU-87/89 munitions (on rack assemblies); or 16 GBU-31 JDAMs, 16 Mk 84 (2,000-lb) bombs, 16 AGM-154 JSOWs, 16 AGM-158 JASSMs, or eight GBU-28 LGBs.

Accommodation: Two pilots on ACES II zero/zero ejection seats.

#b-2a spirit #usaf #aircraft #aviation

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reverieshifts · 4 days ago

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𝑻𝒉𝒆 𝑪𝒍𝒆𝒎𝒆𝒏𝒕𝒊𝒏𝒆 𝒑𝒕. 𝟐: 𝒅𝒆𝒔𝒊𝒈𝒏 𝒂𝒏𝒅 𝒔𝒚𝒔𝒕𝒆𝒎𝒔

𝒔𝒄𝒊-𝒇𝒊 𝒅𝒓

𝒔𝒉𝒊𝒑 𝒄𝒍𝒂𝒔𝒔 𝒂𝒏𝒅 𝒄𝒐𝒏𝒇𝒊𝒈𝒖𝒓𝒂𝒕𝒊𝒐𝒏

Class: Modified mid-class freighter (original designation untraceable)

Dimensions: Compact and fast—built more for speed and evasion than cargo bulk

Original Use: Unknown. Judging by the design mix, she may have once been a light cargo hauler, but at this point, almost nothing about her is stock.

𝒉𝒖𝒍𝒍 𝒂𝒏𝒅 𝒂𝒓𝒎𝒐𝒓

Plating: Mismatched but reinforced. Some hull panels are standard titanium composite, others are salvaged from military vessels. I once found a piece stamped with a defense contractor logo. Soren played dumb.

Damage Markers: Scars from asteroid grazes, plasma burns, and at least one railgun strike that tore through the starboard side before being patched with a piece of what appears to be an old satellite dish.

Stealth Coating: A stolen stealth coating on one side (only one side), giving her a bizarre half-gloss appearance when flying in certain light.

𝒑𝒓𝒐𝒑𝒖𝒍𝒔𝒊𝒐𝒏 𝒂𝒏𝒅 𝒎𝒂𝒏𝒆𝒖𝒗𝒆𝒓𝒂𝒃𝒊𝒍𝒊𝒕𝒚

Here’s where things get... illegal.

Engine Type: Tri-core fusion drive (overclocked illegally)

Thrusters: Multi-angle vectoring thrusters scavenged from a racing skiff

Hyperspace Drive: Installed after-market. Very not standard. Definitely not licensed. Burns through fuel like sin, but gets the job done.

Maneuverability: Shockingly agile for her size. She’s not built to win dogfights—she’s built to not get hit.

Speed: Capable of outpacing most patrol cruisers and nearly anything in her class. Soren once escaped a blockade by flipping her vertical, killing main thrust, and gliding between two gunships with only manual microthrusters. Clemmy didn’t love that. But she did it.

Max Velocity: Classified (by Soren) as “if she shakes apart, you pushed her too far.”

Signature Trick: Emergency micro-bursts for fast stops or rapid angular shifts—great for dodging, terrible for unsecured passengers.

𝒐𝒇𝒇𝒆𝒏𝒔𝒊𝒗𝒆 𝒔𝒚𝒔𝒕𝒆𝒎𝒔

While not technically a warship, Clemmy has teeth—and Soren is not shy about using them.

Primary Weapons:

Retractable twin plasma cannons mounted under the nose (illegally modified for rapid cycling)

Hidden turret along the dorsal fin with full 360° tracking (camouflaged beneath sensor shielding)

Secondary Systems:

Ion net disruptor (used for disabling ships mid-chase)

Forward grappling harpoon (officially for salvage… unofficially for “creative boarding solutions”)

Mod Notes: All weapons have been internally rewired for faster charge times and energy efficiency. Soren insists it’s “completely safe.” The ship disagrees. The floor near the control relay is still scorched.

𝒅𝒆𝒇𝒆𝒏𝒔𝒊𝒗𝒆 𝒔𝒚𝒔𝒕𝒆𝒎𝒔

Shielding: Layered energy-dispersal field adapted from outdated military specs. It’s finicky, but when tuned right, it can absorb an entire volley without so much as a flicker.

Hull Reinforcement: Polyceramic inner shell under the patchwork hull. Not factory standard. Probably military surplus. Possibly stolen.

Cloaking:

Partial stealth mode: One side only. Meant for short bursts, ambushes, or dodging sensor sweeps. Jax once described it as “trying to hide behind your own arm.”

Signature Dampeners: Basic-grade dampeners, good enough to fool low-level scans or confuse weapons locks for a few seconds.

Countermeasures:

Chaff and flare deployment for missile evasion

ECM scrambler array that definitely violates at least five galactic communication laws

Reinforcement Field: Short-range gravitic pulse projector, used to knock boarding parties off balance or repel magnetic tethers.

𝒏𝒂𝒗𝒊𝒈𝒂𝒕𝒊𝒐𝒏 𝒂𝒏𝒅 𝒑𝒊𝒍𝒐𝒕𝒊𝒏𝒈

Primary Navigation System: Jury-rigged hybrid between an outdated freighter nav-core and a racing AI module. The interface is messy, but the calculations are blindingly fast—when they don’t crash mid-jump.

Manual Controls: Everything important is mapped to tactile controls. Soren doesn’t trust full automation. If the nav AI glitches mid-dive, he wants to feel the override.

Autopilot: Exists. Technically. Mostly used as a glorified parking brake or when Soren needs to sleep for 20 minutes in a safe orbit.

Charting Software: Half-legal, half-pirated. Capable of plotting hyperspace routes through narrow, high-risk corridors that most ships avoid.

Backup Systems: A wall-mounted hardcopy star chart in the cockpit. Just in case. Zia thinks this is hilarious. Soren calls it “responsible.”

𝒅𝒐𝒄𝒌𝒊𝒏𝒈 𝒄𝒂𝒑𝒂𝒄𝒊𝒕𝒚 𝒂𝒏𝒅 𝒂𝒄𝒄𝒆𝒔𝒔

Docking Clamps: Can attach to standard civilian ports, refueling stations, and most illicit trade hubs. May need to be “persuaded” into alignment.

Shuttle Bay: None. She’s too compact for internal hangars. Instead, she has one reinforced top-hatch cradle rigged for small detachable pods—used rarely, and only when absolutely necessary.

Airlocks:

Main Port: Standard-sized, sealed, and usually a bit stubborn when opening.

Secondary Hatch: Hidden behind a supply wall in the engine bay. Used for stealth entries and exits.

𝒓𝒆𝒑𝒂𝒊𝒓 𝒂𝒏𝒅 𝒎𝒂𝒊𝒏𝒕𝒆𝒏𝒂𝒏𝒄𝒆 𝒏𝒆𝒆𝒅𝒔

Routine Repairs: Constant. Something is always groaning, leaking, sparking, or “just about to give out but not yet.”

Spare Parts: Stored in crates scattered across the ship—engine parts in the pantry, coolant lines under the bench seat, wiring spools in my hydroponics pod (which I do not appreciate).

Self-Diagnostics: Unreliable. The system either reports “everything is fine” (it’s not), or starts shrieking about seven simultaneous reactor leaks (there are none). Soren usually ignores it and just listens to the hum of the engine to diagnose problems.

Repairs in Flight: Doable. Often necessary. Soren has made mid-warp hull welds while dangling from a tether. Zia once had to climb into the bulkhead to manually restart a fried fuse bank after a flare surge.

Critical Weakness: The fuel converter. If anything’s going to go first, it’s that. It’s been patched, rewired, and coaxed with offerings—but one day, it’s going to die loudly.

𝒔𝒚𝒔𝒕𝒆𝒎 𝒊𝒏𝒕𝒆𝒈𝒓𝒂𝒕𝒊𝒐𝒏

Power Grid: Custom-wired. Inconsistent. If too many systems are running at once (say, stealth mode, shields, and weapons), things start flickering. Choosing what gets power is sometimes a strategic decision—or a desperate one.

AI Integration: No full AI. Just a scattered handful of voice-assist systems, diagnostic subroutines, and a navigation core that occasionally asks Soren if he’s “sure about that” when he plots something stupid.

Voice Recognition: Primarily responds to Soren’s voice, but Zia has jury-rigged access to certain commands—especially life support, lighting, and doors.

𝒅𝒐𝒄𝒌𝒊𝒏𝒈/𝒃𝒐𝒂𝒓𝒅𝒊𝒏𝒈 𝒇𝒆𝒂𝒕𝒖𝒓𝒆𝒔

Hard-dock only. No fancy mag-coupling or remote landers.

Zero-G Transfer Capability: Yes, with magnetic grip points and a manually sealed transition tunnel.

Boarding Defense: Reinforcement field, sealed bulkheads, and at least three blasters stashed near the doors “just in case.”

𝒔𝒚𝒔𝒕𝒆𝒎 𝒏𝒐𝒕𝒆𝒔

Most systems are custom-built, hotwired, or frankensteined together. Only Soren knows how everything works—and even he sometimes has to hit things to make them run.

Diagnostics require manual calibration. The ship’s internal sensors are either hyper-sensitive or utterly dead.

Flight path records? Wiped. Regularly. On principle.

𝒊𝒏 𝒔𝒉𝒐𝒓𝒕:

Clementine might look like a rustbucket. But she’s got the firepower of a private gunship, the speed of a racer, and the evasive instincts of a hunted animal. She doesn’t win fights with brute force—she wins them by being faster, smarter, and just illegal enough to stay one step ahead of the galaxy’s worst.

𝒆𝒙𝒕𝒓𝒂

Ok, I'm gonna be honest here, my friend who's really into sci-fi had to help me write most of this, because as I've said before, I know like nothing about it. So all the fancy technical stuff in here was all him.

@aprilshiftz @lalalian

#reality shifting #shiftblr #desired reality #shifters #scripting #original dr rambles #reality shifter #dr scrapbook #original dr scrapbook

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mariacallous · 2 months ago

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It used to be that when BMW would refit a factory to build a new car, the only way the automaker could check if the chassis would fit through the production line was to fly a team out and physically push the body through the process, making note of any snags.

Now, process engineers can simply run a simulation, sending a 3D model of the car through a near-identical digital twin of the factory. Any mistakes are spotted before the production line is built, saving time and money.

Such is the power of the industrial metaverse. Forget sending your avatar to virtual meetings with remote colleagues or poker nights with distant friends, as Mark Zuckerberg envisioned in 2021 when he changed Facebook’s name to Meta; the metaverse idea has found its killer app in manufacturing.

While the consumer version of the metaverse has stumbled, the industrial metaverse is expected to be worth $100 billion globally by 2030, according to a World Economic Forum report. In this context, the concept of the metaverse refers to a convergence of technologies including simulations, sensors, augmented reality, and 3D standards. Varvn Aryacetas, Deloitte’s AI strategy and innovation practice leader for the UK, prefers to describe it as spatial computing. “It’s about bridging the physical world with the digital world,” he says. This can include training in virtual reality, digital product design, and virtual simulations of physical spaces such as factories.

In 2022, Nvidia—the games graphics company that now powers AI with its GPUs—unveiled Omniverse, a set of tools for building simulations, running digital twins, and powering automation. It acts as a platform for the industrial metaverse. “This is a general technology—it can be used for all kinds of things,” says Rev Lebaredian, vice president of Omniverse and simulation technology at Nvidia. “I mean, representing the real world inside a computer simulation is just very useful for a lot of things—but it’s absolutely essential for building any system that has autonomy in it.”

Home improvement chain Lowe’s uses the platform to test new layouts in digital twins before building them in its physical stores. Zaha Hadid Architects creates virtual models of its projects for remote collaboration. Amazon simulates warehouses to train virtual robots before letting real ones join the floor. And BMW has built virtual models for all its sites, including its newest factory in Debrecen, Hungary, which was planned and tested virtually before construction.

To simulate its entire manufacturing process, BMW filled its virtual factories with 3D models of its cars, equipment, and even people. It created these elements in an open-source file format originated by Pixar called Universal Scene Description (OpenUSD), with Omniverse providing the technical foundation for the virtual models and BMW creating its own software layers on top, explains Matthias Mayr, virtual factory specialist at BMW.

“If you imagine a factory that would take half an hour to walk from one side to the other side, you can imagine it’s also quite a large model,” Mayr says. Hence turning to a gaming company for the technology—they know how to render scenes you can run through. Early versions of the virtual factory even had gaming-style WASD keyboard navigation, but this was dropped in favor of a click-based interface akin to exploring Google Street View in a browser, so anyone could easily find their way.

BMW also uses Omniverse for collaboration on car design and customization visualizations for customers, but a key benefit is being able to model production lines. New cars mean a new assembly process, but refitting a factory is a daunting process. Previously, key information was held in silos—production crews understood details of the assembly process, external suppliers had specs of new parts or machinery, architects had detailed building plans—and costs would pile up for every delay or mistake. “The later you find a problem, the worse it is,” says Lebaredian.

Now, problems are worked out virtually, with a central location for standardized data to be held. There’s still a critical human element: Mapping a facility requires sending a laser scanner strapped to a person running through a factory to capture point cloud data about how everything is arranged. Design engineers also need to create a 3D model of every stage of a car as it’s assembled. This level of detail allows BMW to virtually test the assembly process, complete with simulations of robotics, machines, and even human workers, as BMW has data tracking how long it takes employees to assemble a part.

The main idea is to avoid errors—does that machine even fit there?—but the system also enables optimization, such as moving a rack of components closer to a particular station to save steps for human assemblers. “You can optimize first and gain a lot of efficiency in the first production, and in the construction phase, you have fewer mistakes,” Mayr says. “It’s less error prone.”

Omniverse being a Nvidia platform, AI is naturally next. BMW is already layering in generative AI to help with navigation of its virtual models—they’re so massive that finding a particular point in the digital factory can still require asking a human expert for directions. But the aim is to use AI to optimize production lines too. “Because you have the whole data available, not just for one plant, it will be able to make good suggestions,” says Mayr—lessons learned in one factory could more easily be applied to others.

And then there’s robotics and other autonomous systems. Here, Omniverse can offer a digital space for testing before deploying in the real world, but it can also generate synthetic training data by running simulations, just as driverless car systems are trained with virtual video footage generated by AI. “Real-world experience isn’t going to come mostly from the real world—it comes from simulation,” says Lebaredian.

Aryacetas predicts that the biggest impact from the industrial metaverse will be embodied or physical AI—in other words, robots. “Robots aren’t fully there yet, but they’re rapidly training up to understand the physical world around them—and that’s being done because of these underlying spatial computing technologies,” he says.

The future of the metaverse isn’t avatars in a virtual world; it’s digital twins teaching industrial robots how to step out into the physical one.

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vatssautomation · 2 months ago

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CNC Press Brake Machine in India: Shaping the Future of Metal Bending

In the dynamic world of metal fabrication, CNC Press Brake Machines have become indispensable. These machines are critical in industries that demand precision bending and forming of sheet metal components. In India, the rising focus on infrastructure development, automotive manufacturing, and localized production has driven the adoption of CNC press brake technology across various sectors.

From small workshops to large-scale factories, CNC press brakes are revolutionizing how Indian manufacturers handle metal forming—efficiently, accurately, and consistently.

What is a CNC Press Brake Machine?

A CNC (Computer Numerical Control) Press Brake Machine is used to bend and shape metal sheets with precision. It uses a punch and die to perform various bends, guided by a CNC system that ensures exact specifications for angle, length, and repetition.

Modern CNC press brakes are far more advanced than traditional mechanical or hydraulic versions. They come with programmable controls, automated back gauges, and advanced sensors to deliver high-speed and high-precision bending.

Why CNC Press Brakes are Gaining Popularity in India

1. Precision and Consistency

In sectors like automotive, aerospace, and electronics, even minor deviations in part dimensions can lead to quality issues. CNC press brakes eliminate human error and ensure consistent output across batches.

2. Growing Industrialization

India’s expanding industrial base, especially in Tier 2 and Tier 3 cities, is fueling demand for reliable fabrication equipment. CNC press brakes allow businesses to scale up production without compromising on accuracy.

3. Labour Efficiency

With a skilled labor shortage and rising wages, automation is becoming more attractive. CNC press brakes require minimal human intervention, reducing labor costs and dependency on manual operators.

4. Government Incentives

Government initiatives like Make in India and Production Linked Incentive (PLI) Schemes are encouraging manufacturers to invest in advanced machinery, including CNC press brakes, for higher productivity.

Key Features of CNC Press Brake Machines in the Indian Market

High-Tonnage Capability: Machines ranging from 30 to 1000+ tons to suit various applications.

CNC Control Systems: Brands like Delem, ESA, and Cybelec offer intuitive interfaces for programming and automation.

Servo-Electric or Hydraulic Drive Systems: Depending on precision, energy efficiency, and speed requirements.

Multi-Axis Back Gauge: Enables complex bends and reduces setup time.

Automatic Tool Changers (ATC): For higher production environments.

Leading Indian and International Brands

India has a strong presence of both domestic and international CNC press brake manufacturers. Some notable names include:

Hindustan Hydraulics

Electropneumatics

Energy Mission

LVD India

Amada (Japan)

Durma (Turkey)

Yawei (China)

These companies offer machines tailored to the needs and budget of Indian manufacturers.

Applications in India

Automobile Body & Chassis Manufacturing

Kitchen Equipment Fabrication

Electrical Enclosures & Cabinets

Elevator and Escalator Components

Construction and Infrastructure Products

Railways and Defence Equipment

Challenges for Indian Buyers

High Initial Investment: CNC press brakes can be capital intensive, though the ROI is excellent over time.

Skill Development: Operators need training to use CNC systems effectively.

After-Sales Service: Choosing a vendor with reliable local support is crucial for maintenance and uptime.

The Road Ahead: Smart Factories & Industry 4.0

India is steadily moving towards smart manufacturing. CNC press brakes are now integrating with IoT, ERP systems, and robotic automation, enabling real-time monitoring, predictive maintenance, and remote troubleshooting. This evolution is making Indian factories more agile and globally competitive.

Conclusion

The CNC Press Brake Machine is no longer a luxury—it's a necessity in modern Indian manufacturing. With its unmatched accuracy, efficiency, and automation capabilities, it empowers businesses to meet rising customer expectations while optimizing operational costs.

As India continues to climb the global manufacturing ladder, CNC press brake machines will play a pivotal role in shaping the future—quite literally.

#CNC Press Brake Machines

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souhaillaghchimdev · 2 months ago

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Getting Started with Industrial Robotics Programming

Industrial robotics is a field where software engineering meets automation to drive manufacturing, assembly, and inspection processes. With the rise of Industry 4.0, the demand for skilled robotics programmers is rapidly increasing. This post introduces you to the fundamentals of industrial robotics programming and how you can get started in this exciting tech space.

What is Industrial Robotics Programming?

Industrial robotics programming involves creating software instructions for robots to perform tasks such as welding, picking and placing objects, painting, or quality inspection. These robots are typically used in factories and warehouses, and are often programmed using proprietary or standard languages tailored for automation tasks.

Popular Robotics Programming Languages

RAPID – Used for ABB robots.

KRL (KUKA Robot Language) – For KUKA industrial robots.

URScript – Used by Universal Robots.

Fanuc KAREL / Teach Pendant Programming

ROS (Robot Operating System) – Widely used open-source middleware for robotics.

Python and C++ – Common languages for simulation and integration with sensors and AI.

Key Components in Robotics Programming

Motion Control: Programming the path, speed, and precision of robot arms.

Sensor Integration: Use of cameras, force sensors, and proximity detectors for adaptive control.

PLC Communication: Integrating robots with Programmable Logic Controllers for factory automation.

Safety Protocols: Programming emergency stops, limit switches, and safe zones.

Human-Machine Interface (HMI): Designing interfaces for operators to control and monitor robots.

Sample URScript Code (Universal Robots)

# Move to position movej([1.0, -1.57, 1.57, -1.57, -1.57, 0.0], a=1.4, v=1.05) # Gripper control (example function call) set_digital_out(8, True) # Close gripper sleep(1) set_digital_out(8, False) # Open gripper

Software Tools You Can Use

RoboDK – Offline programming and simulation.

ROS + Gazebo – Open-source tools for simulation and robotic control.

ABB RobotStudio

Fanuc ROBOGUIDE

Siemens TIA Portal – For integration with industrial control systems.

Steps to Start Your Journey

Learn the basics of industrial robotics and automation.

Familiarize yourself with at least one brand of industrial robot (ABB, KUKA, UR, Fanuc).

Get comfortable with control systems and communication protocols (EtherCAT, PROFINET).

Practice with simulations before handling real robots.

Study safety standards (ISO 10218, ANSI/RIA R15.06).

Real-World Applications

Automated welding in car manufacturing.

High-speed pick and place in packaging.

Precision assembly of electronics.

Material handling and palletizing in warehouses.

Conclusion

Industrial robotics programming is a specialized yet rewarding field that bridges software with real-world mechanics. Whether you’re interested in working with physical robots or developing smart systems for factories, gaining skills in robotics programming can open up incredible career paths in manufacturing, automation, and AI-driven industries.

#programming

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auto2mation1 · 3 months ago

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Factory automation sensors play a crucial role in increasing production speed, efficiency, and accuracy. These smart sensors monitor temperature, pressure, motion, and position, helping manufacturers reduce errors and downtime. By providing real-time data, they improve decision-making, ensuring smooth operations and minimal waste. Automation sensors also enhance safety by detecting malfunctions before they cause major failures. With improved consistency and quality control, factories can meet higher demands without compromising precision. Investing in automation sensors leads to lower costs, higher output, and a competitive edge in manufacturing. Discover how these sensors can revolutionize your production line for faster, smarter operations.

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aippals · 6 months ago

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Industrial Automation and Control

A manufacturing plant's integration of diverse devices, machinery, and equipment forms the basis of industrial automation control systems. However, as previously indicated, they might go one step further and integrate the manufacturing floor system with the rest of the business.

#Energy and Power Automation Solutions #Special Purpose Machine Automation | AI-based vision sensors #Warehouse Automation Solutions #Material Handling Processes #Partner in Factory Automation #Electrical & software solutions #Process Automation Partner

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engineers-heaven · 6 months ago

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Vehicle Design and Manufacturing Processes

Introduction: Vehicle design and manufacturing processes have evolved dramatically over the years. From manual assembly lines to high-tech automation, the automotive industry has witnessed numerous advancements that enhance vehicle performance, safety, and sustainability. This blog explores the latest trends in vehicle design and the manufacturing processes that are transforming the industry.

Design Considerations: Designing a vehicle is a complex and multi-disciplinary process that involves engineering, aerodynamics, ergonomics, safety, and aesthetics. Engineers must consider factors like fuel efficiency, performance, and environmental impact, all while ensuring the vehicle’s safety for occupants and pedestrians.

For example, modern car designs prioritize aerodynamics to reduce fuel consumption, with sleek shapes and specialized components that minimize air resistance. Additionally, the safety of the vehicle is ensured by incorporating advanced safety systems, such as collision avoidance technologies, airbags, and crumple zones.

Manufacturing Technologies: The rise of automation has revolutionized vehicle manufacturing. Robotic arms, AI, and 3D printing are now integral to automotive production. Robotics allows for faster and more precise assembly, while AI systems help in predicting maintenance needs and optimizing production schedules.

One significant advancement is the use of 3D printing for creating prototype parts and even some vehicle components. This technology enables manufacturers to design and produce intricate parts with reduced material waste and lower costs. Additionally, automation has sped up assembly lines, allowing for mass production while maintaining consistent quality.

Sustainability: As the world becomes more eco-conscious, the automotive industry has shifted toward more sustainable practices. Electric vehicles (EVs) are at the forefront of this revolution, offering a cleaner alternative to traditional gasoline-powered cars. In addition to EVs, car manufacturers are adopting environmentally friendly materials, such as recycled plastics and plant-based composites, to reduce the carbon footprint of their vehicles.

Furthermore, energy-efficient manufacturing practices, such as using renewable energy to power factories and reducing waste, are helping the industry move toward a more sustainable future.

Future Trends: The future of vehicle design and manufacturing is exciting. One of the biggest trends is the development of autonomous vehicles, which use sensors, AI, and machine learning to navigate roads without human intervention. These vehicles promise to increase safety, reduce traffic, and improve transportation efficiency.

Modular vehicle design is also gaining traction. This approach allows manufacturers to produce customizable vehicles with interchangeable components, which can be tailored to meet different customer needs.

Conclusion: The automotive industry is undergoing a revolution, driven by innovative design principles and advanced manufacturing technologies. As sustainability becomes increasingly important and new technologies such as autonomous driving and electric vehicles take center stage, the future of vehicle design looks promising. By continuing to prioritize safety, efficiency, and environmental responsibility, the industry will continue to transform how we think about transportation.

For comprehensive information and resources on engineering topics, please visit the Engineer's Heaven website.

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throatofdelusion12 · 11 months ago

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So for all my moots that play minecraft

Have you ever wanted automated factories that are simple and easy to understand

What about automated digging

Or automated both

Then all you have to do in order from left to right

Place a crafter (this shit is so helpful)

Then a sculk sensor

Then an observer

Then a dispenser

(This is not exclusively for tnt, you could use it for arrows, fire charges, easy flying machines that drop any items that shoot out of dispensers)

#minecraft

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govindhtech · 9 months ago

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Agilex 3 FPGAs: Next-Gen Edge-To-Cloud Technology At Altera

Agilex 3 FPGA

Today, Altera, an Intel company, launched a line of FPGA hardware, software, and development tools to expand the market and use cases for its programmable solutions. Altera unveiled new development kits and software support for its Agilex 5 FPGAs at its annual developer’s conference, along with fresh information on its next-generation, cost-and power-optimized Agilex 3 FPGA.

Altera

Why It Matters

Altera is the sole independent provider of FPGAs, offering complete stack solutions designed for next-generation communications infrastructure, intelligent edge applications, and high-performance accelerated computing systems. Customers can get adaptable hardware from the company that quickly adjusts to shifting market demands brought about by the era of intelligent computing thanks to its extensive FPGA range. With Agilex FPGAs loaded with AI Tensor Blocks and the Altera FPGA AI Suite, which speeds up FPGA development for AI inference using well-liked frameworks like TensorFlow, PyTorch, and OpenVINO toolkit and tested FPGA development flows, Altera is leading the industry in the use of FPGAs in AI inference workload

Intel Agilex 3

What Agilex 3 FPGAs Offer

Designed to satisfy the power, performance, and size needs of embedded and intelligent edge applications, Altera today revealed additional product details for its Agilex 3 FPGA. Agilex 3 FPGAs, with densities ranging from 25K-135K logic elements, offer faster performance, improved security, and higher degrees of integration in a smaller box than its predecessors.

An on-chip twin Cortex A55 ARM hard processor subsystem with a programmable fabric enhanced with artificial intelligence capabilities is a feature of the FPGA family. Real-time computation for time-sensitive applications such as industrial Internet of Things (IoT) and driverless cars is made possible by the FPGA for intelligent edge applications. Agilex 3 FPGAs give sensors, drivers, actuators, and machine learning algorithms a smooth integration for smart factory automation technologies including robotics and machine vision.

Agilex 3 FPGAs provide numerous major security advancements over the previous generation, such as bitstream encryption, authentication, and physical anti-tamper detection, to fulfill the needs of both defense and commercial projects. Critical applications in industrial automation and other fields benefit from these capabilities, which guarantee dependable and secure performance.

Agilex 3 FPGAs offer a 1.9×1 boost in performance over the previous generation by utilizing Altera’s HyperFlex architecture. By extending the HyperFlex design to Agilex 3 FPGAs, high clock frequencies can be achieved in an FPGA that is optimized for both cost and power. Added support for LPDDR4X Memory and integrated high-speed transceivers capable of up to 12.5 Gbps allow for increased system performance.

Agilex 3 FPGA software support is scheduled to begin in Q1 2025, with development kits and production shipments following in the middle of the year.

How FPGA Software Tools Speed Market Entry

Quartus Prime Pro

The Latest Features of Altera’s Quartus Prime Pro software, which gives developers industry-leading compilation times, enhanced designer productivity, and expedited time-to-market, are another way that FPGA software tools accelerate time-to-market. With the impending Quartus Prime Pro 24.3 release, enhanced support for embedded applications and access to additional Agilex devices are made possible.

Agilex 5 FPGA D-series, which targets an even wider range of use cases than Agilex 5 FPGA E-series, which are optimized to enable efficient computing in edge applications, can be designed by customers using this forthcoming release. In order to help lower entry barriers for its mid-range FPGA family, Altera provides software support for its Agilex 5 FPGA E-series through a free license in the Quartus Prime Software.

Support for embedded applications that use Altera’s RISC-V solution, the Nios V soft-core processor that may be instantiated in the FPGA fabric, or an integrated hard-processor subsystem is also included in this software release. Agilex 5 FPGA design examples that highlight Nios V features like lockstep, complete ECC, and branch prediction are now available to customers. The most recent versions of Linux, VxWorks, and Zephyr provide new OS and RTOS support for the Agilex 5 SoC FPGA-based hard processor subsystem.

How to Begin for Developers

In addition to the extensive range of Agilex 5 and Agilex 7 FPGAs-based solutions available to assist developers in getting started, Altera and its ecosystem partners announced the release of 11 additional Agilex 5 FPGA-based development kits and system-on-modules (SoMs).

Developers may quickly transition to full-volume production, gain firsthand knowledge of the features and advantages Agilex FPGAs can offer, and easily and affordably access Altera hardware with FPGA development kits.

Kits are available for a wide range of application cases and all geographical locations. To find out how to buy, go to Altera’s Partner Showcase website.