IoT in Agriculture is Booming!

Industries are shifting towards evolution with trending technologies like Internet of Things (IoT), AR/VR, AI and machine learning. IoT (one of them) is having more impact as it seamlessly uses consistent connectivity, helping different platforms to perform efficiently.

Countries are engaging with the leading IoT development companies to make their agriculture industry better year by year. With endless possibilities to utilize IoT applications, governments are taking necessary steps to make the industry smart with intelligent systems.

Solutions like automated analytics, intelligent data systems, and digitally-equipped crop management platforms, can make a huge difference as compared to traditional systems. As a result, there is a great impact on organic farming, cropping, and other agricultural activities that can be benefited with IoT solutions.

Embedded Computing Marled is Anticipated to Witness High Growth Owing to Wide Adoption Across End-use Industries

Embedded computing refers to a computer system that is part of a larger mechanical or electrical system designed to perform a dedicated function. Embedded systems are designed for specific control functions within embedded products and machines and operate under the direct control of an embedded program. Some key features of embedded systems include rugged construction, low power usage, real-time operating capabilities and compact size. Embedded devices are commonly found in industrial equipment, automobiles, consumer electronics, home appliances and medical devices to control electronic systems. Their key advantage is the ability to control electronic processes in a precise, flexible and cost-effective manner.

The global embedded computing market is estimated to be valued at US$ 112.45 Bn in 2024 and is expected to reach US$ 174.38 Bn by 2031, exhibiting a compound annual growth rate (CAGR) of 6.5% from 2024 to 2031.

Wide adoption across industries such as industrial automation, transportation, healthcare, telecommunication and consumer electronics is fueling market growth. Embedded systems allow streamlining of electronic processes, reducing downtimes and operation costs for end-use industries. Key Takeaways Key players operating in the embedded computing market are Advanced Micro Devices (AMD), Inc., Advantech Co., Ltd., Avalue Technology Inc., Curtiss-Wright Corporation, Dell Technologies Inc., Emerson Electric Co., Fujitsu Limited, General Electric Company, Hewlett Packard Enterprise Company, Honeywell International Inc., Intel Corporation, Kontron ST AG, Mitsubishi Electric Corporation, Rockwell Automation, Inc., and Texas Instruments Incorporated. The Embedded Computing Market Demand offers significant opportunities for system integrators and solution providers through new product development and capability expansion. Growing digitization trends across industry verticals will continue to generate strong demand for embedded systems with advanced computing and connectivity features. Leading embedded computing companies are focusing on global expansion strategies through partnerships, joint ventures and acquisitions to solidify their presence in emerging economies of Asia Pacific, Latin America, Middle East and Africa. These regions offer high growth potential driven by ongoing modernization of infrastructure and growing electronics manufacturing activities. Market Drivers Wide adoption across industrial automation applications is a key driver for the embedded computing market. Use of embedded systems allows streamlining of electronic processes, reducing downtimes and operation costs for industrial equipment manufacturers. Growing connectivity trends through Industrial Internet of Things (IIoT) will further propel demand. Rising electronics content in automobiles is positively impacting the market. Advanced driver assistance systems, infotainment systems and vehicle networking require powerful embedded computing solutions. Strict fuel efficiency and vehicle emissions norms will accelerate integration of embedded computing hardware. Market Restrain Design complexity of developing embedded system on a chip (SoC) poses challenges, especially for integrating advanced Embedded Computing Companies capabilities with low power requirements. This increases new product development timelines and costs. Limited standardization across various embedded system platforms inhibits seamless interoperability, data exchange and application portability. This poses difficulties for globally distributed product development activities.

Segment Analysis Automotive industrial and transportation is dominating the embedded computing market due to increasing implementation of advanced driver-assistance systems, connected vehicles solutions, electric vehicles, and autonomous vehicles. According to recent surveys over 65% of all new light vehicles shipped will have features like adaptive cruise control, automatic emergency braking, and blind spot monitoring by 2030. All these emerging technologies are driving the growth of embedded systems in automotive applications. Security and defense is another major sub segment in the embedded computing market owing to rising implementation of thermal weapon sights, combat management systems, imaging payloads and guidance systems in warships, aircraft carriers and fighter jets. Real-time information, enhanced situational awareness and integrated mission capabilities are some key priorities for embedded systems in defense applications. Various nations are also focusing on developing autonomous weapons which will further augment demand in coming years. Global Analysis North America dominates the global embedded computing market with a share of over 35% due to substantial research funding and presence of major OEMs in the region. US and Canada are hub for embedded technology development owing to advancement in networking infrastructure, IoT penetration and adoption of Industry 4.0 concepts. Asia Pacific shows fastest growth momentum led by China, India, Japan and South Korea. Low manufacturing cost and government initiatives to digitize industries are driving Asia Pacific market. Intensifying Sino-US trade war may impact supply chain dynamics in long run. Europe captures around 25% market share led by Germany, United Kingdom and France.

Get more insights on Embedded Computing Market

About Author:

Money Singh is a seasoned content writer with over four years of experience in the market research sector. Her expertise spans various industries, including food and beverages, biotechnology, chemical and materials, defense and aerospace, consumer goods, etc. (https://www.linkedin.com/in/money-singh-590844163)

Teksun Inc is an ISO 9001:2015 certified IoT and AI Solutions Company specializing in Product Engineering Services supporting ODM & OEM for numerous B2B Applications & Use Cases. To know more about browse: https://teksun.com/ Contact us ID: [email protected]

What Future Trends in Software Engineering Can Be Shaped by C++

The direction of innovation and advancement in the broad field of software engineering is greatly impacted by programming languages. C++ is a well-known programming language that is very efficient, versatile, and has excellent performance. In terms of the future, C++ will have a significant influence on software engineering, setting trends and encouraging innovation in a variety of fields. 

In this blog, we'll look at three key areas where the shift to a dynamic future could be led by C++ developers.

1. High-Performance Computing (HPC) & Parallel Processing

Driving Scalability with Multithreading

Within high-performance computing (HPC), where managing large datasets and executing intricate algorithms in real time are critical tasks, C++ is still an essential tool. The fact that C++ supports multithreading and parallelism is becoming more and more important as parallel processing-oriented designs, like multicore CPUs and GPUs, become more commonplace.

Multithreading with C++

At the core of C++ lies robust support for multithreading, empowering developers to harness the full potential of modern hardware architectures. C++ developers adept in crafting multithreaded applications can architect scalable systems capable of efficiently tackling computationally intensive tasks.

C++ Empowering HPC Solutions

Developers may redefine efficiency and performance benchmarks in a variety of disciplines, from AI inference to financial modeling, by forging HPC solutions with C++ as their toolkit. Through the exploitation of C++'s low-level control and optimization tools, engineers are able to optimize hardware consumption and algorithmic efficiency while pushing the limits of processing capacity.

2. Embedded Systems & IoT

Real-Time Responsiveness Enabled

An ability to evaluate data and perform operations with low latency is required due to the widespread use of embedded systems, particularly in the quickly developing Internet of Things (IoT). With its special combination of system-level control, portability, and performance, C++ becomes the language of choice.

C++ for Embedded Development

C++ is well known for its near-to-hardware capabilities and effective memory management, which enable developers to create firmware and software that meet the demanding requirements of environments with limited resources and real-time responsiveness. C++ guarantees efficiency and dependability at all levels, whether powering autonomous cars or smart devices.

Securing IoT with C++

In the intricate web of IoT ecosystems, security is paramount. C++ emerges as a robust option, boasting strong type checking and emphasis on memory protection. By leveraging C++'s features, developers can fortify IoT devices against potential vulnerabilities, ensuring the integrity and safety of connected systems.

3. Gaming & VR Development

Pushing Immersive Experience Boundaries

In the dynamic domains of game development and virtual reality (VR), where performance and realism reign supreme, C++ remains the cornerstone. With its unparalleled speed and efficiency, C++ empowers developers to craft immersive worlds and captivating experiences that redefine the boundaries of reality.

Redefining VR Realities with C++

When it comes to virtual reality, where user immersion is crucial, C++ is essential for producing smooth experiences that take users to other worlds. The effectiveness of C++ is crucial for preserving high frame rates and preventing motion sickness, guaranteeing users a fluid and engaging VR experience across a range of applications.

C++ in Gaming Engines

C++ is used by top game engines like Unreal Engine and Unity because of its speed and versatility, which lets programmers build visually amazing graphics and seamless gameplay. Game developers can achieve previously unattainable levels of inventiveness and produce gaming experiences that are unmatched by utilizing C++'s capabilities.

Conclusion

In conclusion, there is no denying C++'s ongoing significance as we go forward in the field of software engineering. C++ is the trend-setter and innovator in a variety of fields, including embedded devices, game development, and high-performance computing. C++ engineers emerge as the vanguards of technological growth, creating a world where possibilities are endless and invention has no boundaries because of its unmatched combination of performance, versatility, and control.

FAQs about Future Trends in Software Engineering Shaped by C++

How does C++ contribute to future trends in software engineering?

C++ remains foundational in software development, influencing trends like high-performance computing, game development, and system programming due to its efficiency and versatility.

Is C++ still relevant in modern software engineering practices?

Absolutely! C++ continues to be a cornerstone language, powering critical systems, frameworks, and applications across various industries, ensuring robustness and performance.

What advancements can we expect in C++ to shape future software engineering trends?

Future C++ developments may focus on enhancing parallel computing capabilities, improving interoperability with other languages, and optimizing for emerging hardware architectures, paving the way for cutting-edge software innovations.

Tamagotchi Uni Uses AWS, Amazon Web Services

The Tamagotchi Uni is the first Tamagotchi to ever connect to Wi-Fi, which enables it to receive over the area updates, programing changes, and more. How exactly is this all being done by Bandai Japan? Well Bandai has built the Tamagotchi Uni on the Amazon Web Services platform (AWS).

The details of this are actually outlined on a recent article on the Amazon Web Services blog. The blog post provided a detailed view on how Tamagotchi Uni use AWS to achieve secure and reliable connectivity and quickly deliver new content updates without leaving customers waiting.It details that Bandai Co., Ltd., the company responsible for product development and sales, adopted AWS IoT to realize the concept of globally interconnected Tamagotchi, enabling users to interact with each other.

Bandai partnered with their cloud development partner, Phoenisys, Inc., to connect and manage million of Tamagotchi devices. One of the critical features was the over the air software updates which uses the jobs feature of AWS IoT Device Management to distribute the latest firmware across all Tamagotchi devices without causing any delays to customers.

To make Tamagotchi Uni IoT-enabled, Bandai establish the three key goals, which was implementing secure connections, scaling the load-balancing resources to accommodate over 1 million connections worldwide, and optimizing operational costs. The article even features the AWS architecture for the Tamagotchi Uni, which is interesting.

AWS IoT Core is used to manage the state of each Tamagotchi Uni device, which helps retrieve distributed items and content. AWS IoT Device Management is used to index the extensive Tamagotchi Uni fleet and create dynamic groups on the state of each device, facilitating efficient over-the-air (OTA) updates. FreeRTOS is used to minimize the amount of resources and code required to implement device-to-cloud communication for efficient system development. AWS Lambda is used to process tasks, delivering new announcements, and registering assets. Amazon DynamoDB is used as a fully managed, sever less, key-value noSQL database that runs high-performance applications at any scale. Amazon Simple Storage Service (Amazon S3) is used for object storage service, each of these data stores are used to manage the various resources within Tamagotchi Uni. Lastly, Amazon Timestream is used to accumulate historical data of user’s actions like downloading items and additional content.

The article also details how Bandai is handling large scale firmware updates to Tamagotchi Uni devices which are executed at a rate of 1,000 units per hour which would have resulted in a delay for some devices. The team actually designed job delivery as a continuous job which automatically updates the devices under certain conditions. This is using fleet indexing that runs a query to see which devices meet the criteria for the update to be pushed out to it.

Lastly the article details how Bandai conducted system performance testing at a large-scale to emulate what it would be like after the device was released. They verified the smooth operation and performance of updates through their testing.

Be sure to check out the full article here on the Amazon AWS blog.

Build an IoT project, the easy way! 🔌💡🌐

WipperSnapper is a firmware designed to turn any WiFi-capable board into an Internet-of-Things device without programming a single line of code.

Transform Your IoT Vision with MeshTek's Expert Development Services

MeshTek offers top-notch development services for IoT solutions, helping you transform your ideas into reality. With expertise in hardware design, firmware development, cloud integration, and mobile app development, MeshTek ensures seamless connectivity and efficient performance for your IoT devices. Partner with us to leverage cutting-edge technology and innovative solutions tailored to your specific needs. Discover the future of IoT with MeshTek's comprehensive development services.

Azure IoT Central: Revolutionizing IoT Solutions for Manufacturing Industries

Azure IoT Central is a cutting-edge platform built on the foundation of Azure IoT, offering a model-based approach to empower businesses in constructing enterprise-grade IoT solutions. Designed with the aim of eliminating the need for cloud-solution development expertise, Azure IoT Central provides a comprehensive software as a service (SaaS) solution. With its built-in templates for various industries, device provisioning services, and feature-rich dashboards, it enables seamless monitoring of device health, connectivity, management, and communication.

Streamlining Manufacturing Operations with Azure IoT Central

In the realm of manufacturing, Azure IoT Central proves to be a game-changer by facilitating the seamless connection, management, and monitoring of industrial assets. By leveraging Azure IoT Central, manufacturing industries can effortlessly integrate data into their applications, enabling them to make data-driven decisions and unlock operational efficiencies. With its user-friendly interface and powerful capabilities, Azure IoT Central empowers manufacturers to gain valuable insights from their assets and drive productivity.

Key Features and Benefits

Template-based Solution: Azure IoT Central offers pre-built templates tailored for various industries, enabling businesses to quickly deploy IoT solutions without extensive customization. These templates encompass a wide range of applications, including asset tracking, predictive maintenance, and remote monitoring, among others.

Device Provisioning Services: Simplifying the process of onboarding devices, Azure IoT Central provides robust device provisioning services. This feature streamlines the connection and configuration of devices, ensuring seamless integration into the IoT ecosystem.

Comprehensive Dashboard: Azure IoT Central's intuitive dashboard empowers businesses to monitor and manage their IoT devices effectively. From tracking device health and connectivity to managing firmware updates and troubleshooting, the dashboard provides real-time insights and facilitates proactive maintenance.

Secure and Scalable: Built on the trusted Azure IoT platform, Azure IoT Central ensures top-notch security for sensitive data and device communications. Moreover, it offers scalability to accommodate growing business needs, allowing seamless expansion without compromising performance.

Integration Capabilities: Azure IoT Central seamlessly integrates with other Azure services, such as Azure Machine Learning and Azure Stream Analytics, enabling advanced analytics, machine learning capabilities, and seamless data integration across the Azure ecosystem.

Unlocking the Potential of IoT in Manufacturing

By harnessing the power of Azure IoT Central, manufacturing industries can revolutionize their operations and tap into the full potential of IoT. Here's how Azure IoT Central can benefit manufacturing businesses:

Enhanced Operational Efficiency: Real-time monitoring and analysis of industrial assets enable proactive maintenance, minimizing downtime and optimizing operations. Predictive maintenance and condition monitoring enable businesses to identify and address potential issues before they escalate.

Improved Product Quality: IoT-enabled sensors and devices collect data throughout the production process, ensuring quality control and adherence to standards. Businesses can gain valuable insights into product performance, identify defects, and take corrective measures promptly.

Cost Optimization: By leveraging Azure IoT Central, manufacturers can optimize resource allocation, reduce energy consumption, and streamline maintenance processes. Data-driven insights enable businesses to make informed decisions, resulting in cost savings and improved profitability.

Enhanced Safety and Compliance: IoT devices and sensors can monitor environmental conditions, ensuring a safe working environment for employees. Moreover, businesses can leverage IoT data to comply with industry regulations and maintain quality standards.

Get Started with Azure IoT Central Today

Take the first step toward transforming your manufacturing operations with Azure IoT Central. Leverage its advanced features, comprehensive templates, and user-friendly interface to build robust IoT solutions that propel your business forward. Embrace the power of data, streamline your operations, and unlock unparalleled insights with Azure IoT Central.

Offshore embedded firmware development

In today’s digital age, embedded software development has become the backbone of innovation, enabling devices to function seamlessly and efficiently. As industries across the globe undergo rapid transformation, the demand for sophisticated embedded solutions continues to rise. Avench Systems, a leader in embedded software development, is at the forefront of this technological evolution, delivering high-quality solutions that empower businesses to stay ahead of the curve.

Understanding Embedded Software Development

Embedded software refers to specialized programming integrated into hardware devices, enabling them to perform specific tasks. Unlike traditional software, which operates on general-purpose computers, embedded software is designed to run on microcontrollers or microprocessors within devices. It’s an essential component in various applications, from consumer electronics and automotive systems to industrial machinery and healthcare devices.

The complexity of embedded systems requires a deep understanding of both software and hardware. Developing embedded software involves unique challenges, including real-time performance constraints, limited memory and processing power, and the need for reliability and security. Avench Systems excels in navigating these challenges, providing robust and efficient solutions tailored to each client’s unique requirements.

Avench Systems: Pioneering Excellence in Embedded Software

Avench Systems has established itself as a premier provider of embedded software development services. With a dedicated team of engineers and developers, the company offers end-to-end solutions that cover everything from concept design and prototyping to software development and testing.

Key Strengths of Avench Systems:

Expertise Across Industries: Avench Systems brings extensive experience across a range of industries, including automotive, consumer electronics, industrial automation, and IoT. This diverse expertise enables the company to develop innovative solutions that address the unique challenges of each sector.

Customized Solutions: Understanding that no two projects are alike, Avench Systems takes a personalized approach to every engagement. The company works closely with clients to understand their specific needs and develop custom solutions that align with their business objectives.

Quality and Reliability: At Avench Systems, quality is paramount. The company adheres to stringent quality standards throughout the development process, ensuring that every solution is reliable, secure, and performs optimally in real-world environments.

Advanced Tools and Technologies: Avench Systems leverages the latest tools and technologies in embedded software development. From advanced microcontrollers and real-time operating systems to sophisticated debugging and testing tools, the company is equipped to tackle even the most complex development challenges.

Collaborative Approach: Collaboration is key to Avench Systems’ success. The company fosters a collaborative environment, working closely with clients, partners, and stakeholders to ensure that every project is delivered on time, within budget, and to the highest standards of excellence.

Innovations Driving the Future

As technology continues to evolve, Avench Systems is committed to staying at the cutting edge of innovation. The company is actively exploring new areas of embedded software development, such as artificial intelligence, machine learning, and advanced data analytics. By integrating these technologies into embedded systems, Avench Systems is helping clients create smarter, more connected devices that deliver enhanced functionality and user experiences.

In addition, Avench Systems is focusing on the growing demand for IoT solutions. The company is developing embedded software that enables seamless connectivity and communication between devices, paving the way for more efficient and automated systems in smart homes, industrial settings, and beyond.

Conclusion

Embedded software development is a critical component of modern technology, driving innovation and enabling new possibilities across a wide range of industries. Avench Systems, with its expertise, commitment to quality, and forward-thinking approach, is a trusted partner for businesses seeking to harness the power of embedded systems.

As industries continue to evolve and the demand for sophisticated embedded solutions grows, Avench Systems is well-positioned to lead the way. With a focus on delivering customized, high-quality solutions that meet the unique needs of each client, the company is helping to shape the future of technology, one innovative solution at a time.

Intel Xeon 6 Server Platforms From MSI And GIGABYTE

Intel Xeon 6 Processors

Leading worldwide server manufacturer MSI unveiled its newest server solutions today, using Intel Xeon 6 processors with Performance Cores (P-cores). These new devices, which are designed to satisfy the various needs of data center workloads, provide compute-intensive jobs exceptional performance.

The newest Intel Xeon processors server solutions from MSI, satisfy a variety of performance and efficiency needs by providing excellent performance throughout a wide range of workloads.

P-core Intel Xeon 6 processors are designed to provide the lowest total cost of ownership (TCO) for general-purpose and high-core computational applications that need great performance. Intel Xeon 6 processors have 128 cores, great memory bandwidth, and sophisticated I/O, which give them the power to handle even the most difficult AI, HPC, and data analytics tasks.

Based on the OCP Datacenter Modular Hardware System (DC-MHS) design, MSI has developed new server systems. These new servers are powered by Intel Xeon 6 processors with P-cores and feature DC-SCM hardware management cards for modular server management and streamlined OpenBMC firmware development. They are perfect for modern cloud service providers and data centers to provide management flexibility and cooling efficiency.

Using a single Intel Xeon 6 processor, the D3071 DC-MHS M-DNO Type-2 Host Processor Module serves as the foundation for two SKUs from MSI designed for high-density core-compute servers: the 2U 2-node CD270-S3071-X2 and the 3U 2-node CD370-S3071-X2 series. These systems are built to handle TDP 500W CPUs with air cooling and are optimized for compute-intensive tasks. They also aim to provide optimal thermal performance.

In order to satisfy the needs of organizations both now and in the future, MSI offers a wide choice of server platforms with Intel Xeon 6 processors, from high-performance AI solutions to cloud-scalable, energy-efficient systems.

Intel Xeon 6 price

Intel Xeon 6 prices vary depending on core count, clock speed, cache size, and model. Prices vary with market circumstances and availability.

Prices in general:

Entry-Level: $300–$1000. These CPUs perform well for general-purpose and light activities.

The mid-range is $1000 to $3000. These CPUs are good for data center and high-performance computing.

High-End: Prices surpass $3000, typically several thousand. These CPUs are optimized for large-scale data analytics, AI, and scientific simulations.

Performance Optimized Intel Xeon 6900-series Servers with P-core for AI, Cloud Computing, Edge & IOT by GIGABYTE

The first wave of GIGABYTE servers for Intel Xeon 6 Processors with P-cores was unveiled today by Giga Computing, a GIGABYTE company and pioneer in the market for generative AI systems and cutting-edge cooling solutions. The new Intel Xeon platform is designed to maximize per-core performance for general purpose applications and workloads that are heavy on computation and artificial intelligence. For certain workloads, GIGABYTE servers are designed to maximize performance by customizing the server architecture to match the chip design and particular workloads.

Intel Xeon 6900

Intel Xeon 6900-series CPUs with P-cores that have up to 128 cores and up to 96 PCIe Gen5 lanes are supported by all new GIGABYTE servers. Furthermore, the 6900-series offers up to 64 lanes of CXL 2.0 and expandable to 12 channel memory for improved performance in memory-intensive tasks. All things considered, this modular SOC architecture has a lot of promise since it can use a common platform to execute design that is optimized for economy and speed.

Single-socket, general-purpose servers

R164 Series: Small 1U chassis supporting a dual-slot GPU and a single Intel Xeon 6 CPU. The primary emphasis of server variety is the storage solution, offering 12x 2.5″ bays or 4x 3.5″/2.5″ bays for SAS, NVMe, and SATA disks.

R264 Series: This series, which now includes a 2U chassis, can accommodate up to 4x dual-slot Gen5 GPUs in addition to a single CPU.

Dual-Socket General Purpose Servers

R184 Series: This series offers comparable storage options to the R164 series, but it has a higher compute density distributed over two CPU sockets. As a result, it places less emphasis on the expansion slots and does not support dual-slot GPUs.

R284 Series: Using a 2U chassis, the increased server height allows for the integration of two CPU sockets and two GPU slots. The R284 series of devices offers up to 24x 2.5″ Gen5 drives or 12x 3.5″/2.5″ mixed storage choices.

Servers on the Edge

E264 Series: This series maintains the option to have a 2U form factor in order to accommodate a single CPU and up to four dual-slot GPUs for customers who want a small chassis depth. Compared to general-purpose servers, the server depth has dropped by over 200 mm, yet total compute performance may still be maintained at the expense of fewer storage bays.

E284 series: It is a twin CPU socket design that prioritizes CPU computing. It has two OCP NIC 3.0 ports and six FHHL extension slots, providing a multitude of I/O choices.

Modularized NVIDIA MGX servers

XV24 Line: This new twin socket series, an NVIDIA OVX optimized server architecture, offers extra FHFL slots for NICs and DPUs in addition to supporting up to four NVIDIA L40S GPUs.

Multi-node, high-density servers

H374 Series: This series provides up to eight CPU sockets distributed across four nodes for the highest density of CPU computing capabilities. Each node further has two or six 2.5″ bays and four low-profile expansion slots.

Server-grade Motherboards

MA34 Series: The MA34-CP0 is a high-quality server board with a tonne of I/O choices. It contains four Gen5 expansion ports, one OCP NIC 3.0 slot, and a wealth of MCIO 8i and SlimSAS connections.

In order to fulfill the changing needs of contemporary computing, GIGABYTE keeps pushing the envelope in server innovation. The new servers, which feature unparalleled speed, adaptability, and efficiency, are based on Intel Xeon 6900-series processors and are intended to enable organizations in a variety of industries.

Because AI, cloud computing, and edge technologies are becoming more and more important to sectors, GIGABYTE is dedicated to keeping its server designs up to date with the newest developments in processor technology, so its clients are prepared to face the challenges of the future.

As the Intel Xeon 6 platform’s potential is further explored, GIGABYTE will have systems ready to support a wide range of workloads and vertical markets. Furthermore, GIGABYTE plans to unveil a new server that incorporates Intel Gaudi 3 GPUs in the next months. Targeting AI workloads, especially generative AI inference workloads, is the goal of this scalable and affordable approach. Additionally, patrons may anticipate seeing it at Atlanta’s SC24.

Read more on govindhtech.com

Why Now is the Best Time to Buy WD Purple Pro 10TB Hard Drives in Bulk

In today’s data-driven world, businesses and individuals alike are constantly seeking reliable and efficient storage solutions. One of the standout products in the market is the WD Purple Pro 10TB (WD101PURP) hard drive. This specialized hard drive, designed primarily for high-performance video surveillance applications, offers numerous advantages that make it an ideal choice for bulk purchasing right now. Here’s why investing in these hard drives in bulk can be beneficial and timely.

1. Increased Demand for Data Storage

The rapid growth of data generation across various sectors — be it from surveillance systems, cloud services, or personal use — has resulted in an increased demand for robust storage solutions. With the rise of smart devices and IoT technology, the need for reliable data storage is at an all-time high. The WD Purple Pro 10TB hard drive is engineered to handle 24/7 workloads, making it a perfect candidate for bulk buying to ensure your data needs are met without interruptions.

2. Cost-Effectiveness of Bulk Purchasing

Purchasing in bulk often comes with significant cost savings. Many suppliers offer discounts or better pricing tiers for larger orders. By buying multiple WD Purple Pro 10TB drives, you can reduce your overall cost per unit. This is particularly beneficial for businesses that need multiple drives for extensive data storage and management. The savings realized from bulk purchasing can be reallocated to other areas of the business, enhancing overall operational efficiency.

3. Enhanced Reliability and Performance

The WD Purple Pro series is built with reliability in mind, designed specifically for surveillance applications that demand high write-intensive workloads. With features such as error recovery controls and optimized performance for high-definition video streaming, these drives can manage up to 64 cameras at once. For businesses investing in surveillance systems, buying these drives in bulk ensures that you have a uniform standard of quality across your storage solutions, minimizing potential performance inconsistencies.

4. Future-Proofing Your Infrastructure

As technology evolves, so does the requirement for storage capacity. The WD Purple Pro 10TB hard drive offers ample space for future data growth. By purchasing these drives in bulk now, businesses can prepare for upcoming expansions and increased data storage needs without the hassle of last-minute purchases. This proactive approach can save time, reduce stress, and help maintain a seamless workflow.

5. Simplified Management and Maintenance

Managing a single type of hard drive across your organization simplifies both IT management and maintenance. By opting for bulk purchases of the WD Purple Pro 10TB drives, IT teams can standardize their storage infrastructure. This standardization facilitates easier troubleshooting, firmware updates, and replacements, leading to a more efficient operational workflow. Additionally, having a surplus of drives on hand ensures that you are always prepared for any unexpected failures.

6. Long-Term Investment

Investing in high-capacity drives like the WD Purple Pro 10TB is a long-term strategy. These drives are built to last, with a focus on endurance and longevity. The ability to continuously write and overwrite data makes them ideal for environments where high write operations are frequent. By purchasing in bulk, you ensure that your organization has access to reliable storage solutions for years to come, protecting your investment against potential future price hikes or supply shortages.

7. Tailored Solutions for Surveillance Needs

The WD Purple Pro drives are tailored for specific applications, particularly surveillance. With features such as AllFrame technology, these drives minimize frame loss and provide smoother playback. If your business is in a sector that relies heavily on video surveillance, now is an excellent time to purchase these drives in bulk. The tailored nature of these drives means you can create a surveillance system that meets your specific needs without compromise.

8. Competitive Edge

In industries where data management is crucial, having the right storage solution can provide a competitive edge. By bulk buying WD Purple Pro 10TB hard drives, businesses can enhance their data capabilities, leading to improved operational efficiencies and decision-making processes. This advantage is particularly significant in sectors like retail, logistics, and security, where timely access to data can influence overall performance.

9. Availability and Supply Chain Stability

Given recent global events, supply chain issues have become a significant concern. Investing in bulk now can mitigate the risk of future shortages or price increases. Many businesses have experienced difficulties in obtaining the required technology due to disruptions in the supply chain. By securing a bulk order of WD Purple Pro 10TB drives, you not only ensure availability but also protect your organization against fluctuating market conditions.

10. Environmentally Friendly Practices

Lastly, bulk purchasing can also align with environmentally friendly practices. Fewer shipments mean reduced carbon footprints and lower resource consumption. By consolidating your purchasing strategy, you can not only save costs but also contribute to more sustainable business practices.

Conclusion

The decision to bulk buy WD Purple Pro 10TB hard drives is backed by a multitude of compelling reasons. From cost savings and enhanced reliability to future-proofing and simplified management, the advantages are clear. In a world where data is king, ensuring you have the right storage solutions in place is paramount. With increasing data demands and a rapidly evolving technological landscape, there has never been a better time to invest in these robust hard drives. By acting now, you can secure your data future, streamline operations, and gain a competitive edge in your industry.

Want to Buy WD Purple Pro 10TB Hard Drives in Bulk from VSTL?

If you’re looking to buy WD Purple Pro 10TB hard drives in bulk, VSTL is an excellent choice. They offer competitive pricing and reliable service, ensuring you get the best value for your investment. Whether you need these drives for surveillance systems or extensive data storage, purchasing in bulk can help you save costs while securing high-performance, dependable storage solutions. With their focus on customer satisfaction, VSTL makes it easy to meet your storage needs efficiently. Don’t miss the opportunity to enhance your data management strategy!

Emertxe Embedded Systems Course with Placement in Bangalore

In today’s technology-driven world, embedded systems are the backbone of innovations ranging from IoT devices to automotive technologies. If you're looking for a career in this high-demand sector, Emertxe’s Embedded Systems Course in Bangalore is your perfect launchpad. With industry-recognized training and a strong placement program, Emertxe is helping aspiring engineers transition into successful embedded systems professionals.

Why Choose Emertxe for Embedded Systems Training?

As one of India’s top embedded systems training institutes, Emertxe stands out for its comprehensive curriculum, experienced faculty, and robust placement support. Here’s why Emertxe is a preferred choice:

1. Industry-Relevant Curriculum

Emertxe’s embedded systems course is meticulously designed to align with current industry trends. The curriculum covers:

Embedded C and Data Structures

Linux Systems Programming

ARM-based Embedded Systems Design

RTOS (Real-Time Operating System)

IoT Systems and Embedded Firmware

This hands-on learning approach ensures that you’re industry-ready by the time you complete the course.

2. 100% Placement Guarantee

One of the biggest benefits of enrolling in Emertxe is the institute’s strong placement support. Emertxe has a stellar track record of placing students in top companies. Through rigorous training and mock interviews, the placement team ensures you’re well-prepared for job opportunities. Some of the hiring partners include:

Intel

Bosch

Samsung

Qualcomm

With a 100% placement guarantee, Emertxe has helped numerous students achieve their dream jobs.

3. Experienced Faculty

The training at Emertxe is led by industry veterans with years of experience in embedded systems and IoT. The faculty provides not only theoretical knowledge but also valuable industry insights and project-based learning.

4. Real-World Projects

The best way to master embedded systems is through practical experience. Emertxe’s course includes hands-on projects like:

Designing Embedded IoT Devices

Building ARM Cortex-Based Applications

Real-Time Systems Development

These projects help you gain real-world skills that can be directly applied in your future career.

5. Bangalore – The Hub for Tech Jobs

Bangalore, often referred to as the Silicon Valley of India, offers immense opportunities for embedded systems professionals. Being located in Bangalore, Emertxe provides students with exposure to a thriving tech ecosystem, making it easier to connect with top companies during placement drives.

Course Highlights at Emertxe

Duration: 6 months

Mode of Learning: Classroom and online

Eligibility: Engineering graduates (ECE, EEE, CSE, and IT)

Certification: Upon course completion, you will receive an industry-recognized certification in embedded systems.

Success Stories of Emertxe Alumni

Many students have transformed their careers through Emertxe. From working in core embedded systems jobs to landing high-paying roles in MNCs, the opportunities are endless. Here are a few success stories from Emertxe alumni:

Sanjeev Kumar – Placed at Qualcomm with a package of 7 LPA

Meghana Reddy – Working as an Embedded Developer at Bosch

Rohan Sharma – Landed an IoT engineer role at Intel

Join Emertxe Today and Kickstart Your Embedded Systems Career!

If you're passionate about technology and want a rewarding career in embedded systems, Emertxe’s Embedded Systems Course with Placement in Bangalore is the ideal starting point. With cutting-edge training and unmatched placement support, you’ll be well-equipped to enter this lucrative field.

Enroll now and become part of a leading tech institute that transforms your career.

Enhancing Battery Life in IoT Smart Camera Hardware Design

In IoT smart home security camera designs, wireless connectivity consumes a significant portion of the power budget. Discover how to manage power efficiently as smart cameras incorporate more processing capabilities.

According to a recent report by Global Market Insights, the smart home security camera market is expected to see significant growth from 2023 to 2032, fueled by a sharp increase in residential criminal activities around the globe.

The U.S. Department of Justice estimates there are approximately 2.5 million burglaries annually. Homeowners are using technology to fight back. IoT adoption in smart homes, such as through easy-to-install video cameras, is boosting detection capabilities and enhancing overall security.

Since these solutions are optimized at the system level, developers of smart IoT video cameras are increasingly integrating machine learning (ML) and artificial intelligence (AI) to address the rapidly expanding security needs. However, there are still some basic challenges for video cameras — and they involve powering devices with batteries that just don’t meet the challenge.

Inherent Challenges With Video Cameras

Today’s top-selling battery-based Wi-Fi smart cameras use batteries — able to last a mere 3 to 6 months. Given the flexibility of IoT devices, the number of devices used, and where they are placed, changing out batteries that often — with the associated costs — is problematic.

Wireless smart cameras often consume a substantial portion of the system’s power — up to 50 percent — just for connectivity, even when they are idle but still connected to the network. Wi-Fi was initially designed for high bandwidth data transfer — not low power. Transmitting radio frequency (RF) consumes immense energy that increases with long-range data transfers.

To fulfill the potential of today’s cloud-connected, always-on, wireless smart video cameras, Wi-Fi transmission needs to operate at power levels comparable to Zigbee and Bluetooth protocols. Achieving these power levels can significantly extend battery life.

This shift towards lower power operation and reduced costs can lead to increased adoption and enable advanced features such as those provided by artificial intelligence (AI) and machine learning (ML).

Design considerations also include integrating Wi-Fi provisioning with Bluetooth Low Energy (BLE). As IoT devices are dynamic, features like Firmware-Over-the-Air (FOTA) can be used to upgrade systems or update AI models. High Wi-Fi throughput supports these updates efficiently, offering operational benefits, lower total cost of ownership, and simplified operation and deployment.

Why is Enhancing Smart Wireless Video Cameras Important?

Wireless smart security cameras and video doorbells monitor activity and respond to motion or sound by sending alerts to a homeowner’s phone or email from the cloud. In contrast, an advanced smart wireless camera with AI capabilities can more precisely distinguish between genuine emergencies and routine occurrences.

AI software uses object modeling and machine learning to continually enhance its functionality and insights. For example, it can recognize a dog running onto the porch as a harmless event and avoid triggering an alert. However, if a window is broken or a package is stolen from the porch, the AI system will record the incident and send a notification.

Cloud-connected smart cameras have three main modes:

Sleep

Wi-Fi idle connected

Active video streaming

In sleep mode, the camera operates at its lowest power level and only activates when a local interrupt, such as a motion sensor trigger or button press, occurs. During this state, current consumption is typically in the range of tens of microamps.

Wi-Fi idle connected requires a slightly higher amount of current, on the order of 100’s of microamps, to monitor for interrupts and to maintain connectivity to the Wi-Fi router to listen for messages from the cloud to wake the system.

With active video streaming, the entire camera system captures and transmits video to a cloud service. This requires a much higher power mode since the camera’s video processor and Wi-Fi chipset are in full operation. In this case, the current consumption can reach approximately 250 mA at 3.3 V.

Maximizing Battery Life is Critical

Maximizing battery life requires minimizing overall current consumption. While this may seem straightforward, it’s far from simple. One key strategy is selecting low-power components for the camera design, including the Wi-Fi chipset, video processor, and power management unit. In such designs, meticulous attention to hardware system design is crucial, as every microamp counts.

By optimizing the functionality to reduce the time spent in high-power modes and efficiently managing system resources, battery life can be significantly extended. For instance, using the Wi-Fi chipset to monitor the system instead of relying on the video processor can greatly increase the operating time of a camera.

Two major challenges in designing video IoT devices are ensuring long battery life and providing reliable wireless cloud connectivity. Surprisingly, only about 10% of video cameras are battery-operated, largely due to battery life constraints. Transitioning to a wireless format has been particularly challenging, as power-hungry Wi-Fi can quickly deplete the batteries of video cameras.

Fortunately, advanced technologies now offer solutions to this issue. With optimized embedded hardware and software solutions, like those provided by Silicon Signals, power consumption can be drastically reduced. This enables battery-operated devices to last longer while maintaining the untethered wireless connectivity required for cloud-based applications. For instance, cloud-connected smart video cameras can now be designed with smaller batteries without compromising on battery life, giving designers greater flexibility in creating compact, efficient, and long-lasting products.

Enabling Technology Based on Digital Polar Radio

Let’s delve into the cutting-edge technology that powers Silicon Signals’ IoT solutions. At the heart of extending battery life for video cameras and enabling a range of future features is our advanced ultra-low power Wi-Fi and BLE platform. By leveraging our innovative digital polar radio design, we effectively address the challenges of power-hungry processing seen in previous radio architectures.

Contrary to the common belief that Wi-Fi consumes too much power for battery-operated devices, our technology defies this assumption. It allows cameras to operate without being tethered to wired connections for both power and network, thus improving data accuracy for cloud processing and offering greater placement flexibility for IoT devices. This approach not only enhances battery life but also paves the way for more versatile and efficient smart solutions.

Proven in the IoT Field

Silicon Signals’ advanced technology is making significant strides in various IoT applications, including enhanced baby monitors, security cameras, video doorbells, access control systems, and identity verification. Our ultra-low power Wi-Fi and BLE platform is at the core of these innovations.

For instance, our AI-enabled smart video cameras, powered by this cutting-edge platform, offer battery life that is 2–3 times longer than current solutions, and even extend to multiple years when combined with a solar panel.

In the realm of smart homes, security systems with real-time threat detection, monitoring, and alerts are essential. Our technology addresses this need by providing IoT Wi-Fi video cameras with significantly longer battery life and efficient power management. This advancement is driving quicker adoption and fostering new, innovative use cases. Additionally, our platform enhances the performance of firmware and AI model updates through high-speed data throughput, ensuring that devices stay current with the latest technology and security improvements.

Teksun Inc is a leading Next Generation IoT and AI turn-key Product Engineering Services provider. Teksun is an ISO 9001:2015 certified company headquartered in Silicon Valley, California To know more about browse: https://teksun.com/ Contact us ID: [email protected]

What is the importance of Python and C in the Internet of Things (IoT)?

Python and C complement each other in IoT development, offering particular benefits in distinct layers of IoT development.

Python in IoT

This is widely used in IoT due to several factors that contribute to this state of affairs:

Readability and Ease of Use: Python is written with clean syntax and high abstractions, making it really comfortable to learn and use, even for developers with poor prior experience in programming.

Rich Ecosystem: Python has an extensive ecosystem of libraries and frameworks such as NumPy, Pandas, TensorFlow, and PyTorch that provide essential support for data analysis in IoT applications, machine learning, and deep learning.

 Rapid Prototyping: Interpretable nature allows users to build and test quickly. Therefore, Python provides the best suitability in the prototyping of IoT applications and iterations in design.

Key IoT Applications of Python:

Data Analysis and Visualization: Sensor data processing, analysis, and creating visualizations of that information in pursuit of understanding patterns and trends. 

Machine Learning: Building predictive models for tasks such as anomaly detection, predictive maintenance, and energy optimization. 

IoT Gateway Development: Software development of the gateways by which IoT devices connect to the cloud or other networks. 

C for IoT C is a low-level and efficient language; it plays a very important role in IoT development, especially when:

Performance is key: The fact that C is a compiled language and can interact with hardware elements directly allows for efficiency in execution and thus applies to applications that require real-time control and processing. 

Resource constraint: IoT devices normally have limited processing capability and memory. The role of C in optimizing code to work in an resource-constrained environment is very important. 

Hardware interaction: C interacts directly with the hardware elements, allowing for thorough control and customization of the IoT device. 

Key applications of C in IoT:

Firmware Development in Devices: Core software development running inside IoT devices, managing sensors and actuators, and communication protocols. 

Embedded Systems: The development of embedded systems that integrate hardware and software for specific IoT applications. Real-time Control Development of real-time algorithms targeting motor control, robotics, process automation, and so on. Combining Python and C While Python and C both have their positive attributes, they can quite often be combined to develop a more formidable solution for IoT. For example,

Python for Data Analysis, C for Real-time Control: It may be used to analyze sensor data and make decisions in Python while performing real-time control of actuators based on those decisions in C. 

Python for Prototyping, C for Production: IoT applications might be prototyped quickly in Python, then C is used to optimize the code to a deployment configuration in production.

Hybrid Applications: Some applications would utilize both Python and C coding in a single application, where the higher abstractions are performed using Python, while low-level operations remain with C.

In the knowledge of the strengths and limitations of Python and C, respectively, IoT developers can select appropriate tools for the required functions and thereby develop innovative and efficient solutions.

Trends and Best Practices in Embedded System Software Development

Embedded system software development is evolving rapidly, driven by advancements in technology and the increasing demand for more sophisticated solutions. From smart home devices to industrial automation, embedded systems are at the heart of many innovations. To stay ahead in this competitive field, it’s crucial to be aware of the latest trends and best practices. This blog explores key trends shaping the industry and offers practical advice for developers.

1. Embracing IoT Integration

The Internet of Things (IoT) continues to revolutionize how embedded systems interact with the world. IoT integration allows devices to communicate and share data seamlessly, enhancing their functionality and providing richer user experiences. For developers, this means focusing on secure and efficient data transmission, optimizing connectivity protocols, and ensuring interoperability among diverse devices.

Best Practice: Leverage IoT frameworks and protocols like MQTT or CoAP to streamline data exchange and enhance device compatibility. Ensure robust security measures are in place to protect sensitive data and maintain user privacy.

2. Advancements in Edge Computing

Edge computing is gaining traction as it allows data processing to occur closer to the source, reducing latency and improving performance. This trend is particularly relevant for applications requiring real-time responses, such as autonomous vehicles or industrial robotics.

Best Practice: Design embedded systems with edge processing capabilities to minimize latency and enhance performance. Incorporate local storage and processing power to handle critical tasks efficiently, while still leveraging cloud resources for more intensive operations.

3. Focus on Energy Efficiency

As devices become more power-hungry, energy efficiency has become a top priority in embedded system design. Efficient energy use not only extends the life of battery-operated devices but also contributes to environmental sustainability.

Best Practice: Implement energy-saving techniques such as dynamic voltage and frequency scaling (DVFS) and low-power sleep modes. Optimize algorithms and software to reduce power consumption without compromising performance.

4. Increased Use of Machine Learning and AI

Artificial Intelligence (AI) and Machine Learning (ML) are transforming embedded systems by enabling more intelligent and adaptive behaviors. From predictive maintenance to personalized user experiences, AI and ML are enhancing the capabilities of embedded devices.

Best Practice: Integrate AI and ML algorithms into embedded systems to enable smart functionalities. Choose lightweight models and optimize code to ensure that AI and ML tasks do not overwhelm the system's resources.

5. Enhanced Security Measures

With the rise in connectivity and data sharing, security remains a critical concern in embedded system development. Ensuring robust security measures is essential to protect devices from potential threats and vulnerabilities.

Best Practice: Implement comprehensive security protocols, including encryption, secure boot mechanisms, and regular firmware updates. Conduct thorough security assessments and testing to identify and mitigate potential vulnerabilities.

6. Modular and Scalable Design

Modular design allows for greater flexibility and scalability in embedded systems. By creating components that can be independently developed and integrated, developers can more easily adapt to changing requirements and technological advancements.

Best Practice: Adopt a modular design approach to simplify development and facilitate future upgrades. Use standardized interfaces and protocols to ensure seamless integration of modules and components.

7. Agile Development Methodologies

Agile methodologies are increasingly being adopted in embedded system software development to improve project management and responsiveness. Agile practices promote iterative development, collaboration, and flexibility, enabling teams to adapt to changes and deliver high-quality solutions.

Best Practice: Embrace agile practices such as Scrum or Kanban to enhance project management and streamline development processes. Foster a collaborative environment where feedback is regularly incorporated to refine and improve the system.

8. Focus on User Experience (UX)

User experience is becoming a critical factor in the success of embedded systems. A well-designed user interface can significantly impact how users interact with and perceive a device.

Best Practice: Prioritize user-centered design principles to create intuitive and user-friendly interfaces. Conduct user testing and gather feedback to continuously improve the usability and overall experience of the system.

9. Leveraging Open Source Software

Open source software offers a wealth of resources and community support that can accelerate development and reduce costs. By leveraging open source tools and libraries, developers can build on existing solutions and avoid reinventing the wheel.

Best Practice: Explore open source frameworks and libraries that align with your project needs. Contribute to the open source community to benefit from collective knowledge and innovations.

10. Continuous Integration and Continuous Deployment (CI/CD)

CI/CD practices are increasingly being adopted to streamline the development pipeline and enhance software quality. By automating testing and deployment processes, developers can identify issues early and deliver updates more efficiently.

Best Practice: Implement CI/CD pipelines to automate testing, building, and deployment processes. Regularly integrate and deploy changes to ensure that the system remains stable and up-to-date.

Conclusion

Staying current with the latest trends and best practices in embedded system software development is crucial for creating innovative and high-quality solutions. By embracing IoT integration, focusing on energy efficiency, and incorporating AI and ML, developers can enhance the capabilities of their embedded systems. Prioritizing security, adopting modular design, and leveraging agile methodologies will further contribute to successful project outcomes. As technology continues to advance, staying informed and adaptable will be key to thriving in this dynamic field.

To Know More About ,