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2.4/5 GHz 3.3V Shielded Ultra Small Dual Band WiFi 11a/b/g/n+Ethernet+MCU Module

Genio 510: Redefining the Future of Smart Retail Experiences

Genio IoT Platform by MediaTek

Genio 510

Manufacturers of consumer, business, and industrial devices can benefit from MediaTek Genio IoT Platform’s innovation, quicker market access, and more than a decade of longevity. A range of IoT chipsets called MediaTek Genio IoT is designed to enable and lead the way for innovative gadgets. to cooperation and support from conception to design and production, MediaTek guarantees success. MediaTek can pivot, scale, and adjust to needs thanks to their global network of reliable distributors and business partners.

Genio 510 features

Excellent work

Broad range of third-party modules and power-efficient, high-performing IoT SoCs

AI-driven sophisticated multimedia AI accelerators and cores that improve peripheral intelligent autonomous capabilities

Interaction

Sub-6GHz 5G technologies and Wi-Fi protocols for consumer, business, and industrial use

Both powerful and energy-efficient

Adaptable, quick interfaces

Global 5G modem supported by carriers

Superior assistance

From idea to design to manufacture, MediaTek works with clients, sharing experience and offering thorough documentation, in-depth training, and reliable developer tools.

Safety

IoT SoC with high security and intelligent modules to create goods

Several applications on one common platform

Developing industry, commercial, and enterprise IoT applications on a single platform that works with all SoCs can save development costs and accelerate time to market.

MediaTek Genio 510

Smart retail, industrial, factory automation, and many more Internet of things applications are powered by MediaTek’s Genio 510. Leading manufacturer of fabless semiconductors worldwide, MediaTek will be present at Embedded World 2024, which takes place in Nuremberg this week, along with a number of other firms. Their most recent IoT innovations are on display at the event, and They’ll be talking about how these MediaTek-powered products help a variety of market sectors.

They will be showcasing the recently released MediaTek Genio 510 SoC in one of their demos. The Genio 510 will offer high-efficiency solutions in AI performance, CPU and graphics, 4K display, rich input/output, and 5G and Wi-Fi 6 connection for popular IoT applications. With the Genio 510 and Genio 700 chips being pin-compatible, product developers may now better segment and diversify their designs for different markets without having to pay for a redesign.

Numerous applications, such as digital menus and table service displays, kiosks, smart home displays, point of sale (PoS) devices, and various advertising and public domain HMI applications, are best suited for the MediaTek Genio 510. Industrial HMI covers ruggedized tablets for smart agriculture, healthcare, EV charging infrastructure, factory automation, transportation, warehousing, and logistics. It also includes ruggedized tablets for commercial and industrial vehicles.

The fully integrated, extensive feature set of Genio 510 makes such diversity possible:

Support for two displays, such as an FHD and 4K display

Modern visual quality support for two cameras built on MediaTek’s tried-and-true technologies

For a wide range of computer vision applications, such as facial recognition, object/people identification, collision warning, driver monitoring, gesture and posture detection, and image segmentation, a powerful multi-core AI processor with a dedicated visual processing engine

Rich input/output for peripherals, such as network connectivity, manufacturing equipment, scanners, card readers, and sensors

4K encoding engine (camera recording) and 4K video decoding (multimedia playback for advertising)

Exceptionally power-efficient 6nm SoC

Ready for MediaTek NeuroPilot AI SDK and multitasking OS (time to market accelerated by familiar development environment)

Support for fanless design and industrial grade temperature operation (-40 to 105C)

10-year supply guarantee (one-stop shop supported by a top semiconductor manufacturer in the world)

To what extent does it surpass the alternatives?

The Genio 510 uses more than 50% less power and provides over 250% more CPU performance than the direct alternative!

The MediaTek Genio 510 is an effective IoT platform designed for Edge AI, interactive retail, smart homes, industrial, and commercial uses. It offers multitasking OS, sophisticated multimedia, extremely rapid edge processing, and more. intended for goods that work well with off-grid power systems and fanless enclosure designs.

EVK MediaTek Genio 510

The highly competent Genio 510 (MT8370) edge-AI IoT platform for smart homes, interactive retail, industrial, and commercial applications comes with an evaluation kit called the MediaTek Genio 510 EVK. It offers many multitasking operating systems, a variety of networking choices, very responsive edge processing, and sophisticated multimedia capabilities.

SoC: MediaTek Genio 510

This Edge AI platform, which was created utilising an incredibly efficient 6nm technology, combines an integrated APU (AI processor), DSP, Arm Mali-G57 MC2 GPU, and six cores (2×2.2 GHz Arm Cortex-A78& 4×2.0 GHz Arm Cortex-A55) into a single chip. Video recorded with attached cameras can be converted at up to Full HD resolution while using the least amount of space possible thanks to a HEVC encoding acceleration engine.

FAQS

What is the MediaTek Genio 510?

A chipset intended for a broad spectrum of Internet of Things (IoT) applications is the Genio 510.

What kind of IoT applications is the Genio 510 suited for?

Because of its adaptability, the Genio 510 may be utilised in a wide range of applications, including smart homes, healthcare, transportation, and agriculture, as well as industrial automation (rugged tablets, manufacturing machinery, and point-of-sale systems).

What are the benefits of using the Genio 510?

Rich input/output choices, powerful CPU and graphics processing, compatibility for 4K screens, high-efficiency AI performance, and networking capabilities like 5G and Wi-Fi 6 are all included with the Genio 510.

Read more on Govindhtech.com

Cutting to the "shopping list" section:

We focused on using “off the shelf” components and open-source software to develop the wireless endoscope. This significantly lowered the cost with the goal to make the device accessible for resource-constrained environments. While the technology described is applicable to a variety of rigid lens applications, we attempted to replicate the 4 mm cystoscope lens and separately a clip-on universal endoscope camera.

2.1 Hardware systems

A miniature single-board computer (SBC) module the Raspberry Pi Zero W (Raspberry Pi Foundation, Caldecote, UK) was used because of its size, its low cost (US$10) and its ability to handle high-definition (720p) video.

A 3.7-mm tube camera (model: 1001LG, Shenzhen Eastern International Corporation Limited, Shenzhen, China) was used. It delivers 1280 × 720 high-definition video using a 1/7″ colour CMOS sensor. Lens construction allows a wide (115 degree) field of view and an extended depth of field allowing object in the range of 5 to 50 mm to be in focus. Connectivity is via a USB 2.0 interface with the SBC. The camera is certified IP67 waterproof and the manufacturer is ISO 13485:2016 certified for the design and manufacturer of medical endoscope cameras.

Illumination is via 6 high luminous 0603 white colour LEDs incorporated into the tube camera. The system was powered by a 1200mAh lithium polymer battery and incorporated into a fireproof acrylonitrile butadiene styrene enclosure.

For the clip-on wireless camera module, an 18–35 mm optical zoom coupler (Ouman Medical, Jiangsu Ouman Electronic Equipment Co., ltd, Jiangsu, China) and an 8-megapixel camera module (model: IMX219, Arducam) were used.

2.2 Software systems

Open-source Linux software was used on the SBC as follows:

1. The SBC runs on the Raspbian Pi operating system Lite, a minimal image of Debian Buster [9]. 2. The SBC Wi-Fi module is placed in monitor mode (“hotspot”) using RaspAP [10]. This makes wireless video transmission possible. 3. The video signal is streamed via the UV4L module of “Video 4 Linux 2” [11].

4. Lastly, the wireless video signal is viewed on a standard computer via any internet browser. Figure 2 illustrates the entire software setup.

Fig. 2:

Shenzhen Century Aoke Electronis Co., Ltd. is a leading manufacturer of RF/2.4G Wi-Fi remote control system,module and smart home devices.

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Best Voice Calling Tablets (2024)

While some tablets do not support traditional cellular calls, almost all offer VoIP capabilities through dedicated apps. Tablets with voice-calling features typically come equipped with 3G, 4G, or even 5G connectivity modules, allowing users to make voice calls using a SIM card and take advantage of mobile data services. You can find a selection of top tablets for voice calling on the Gadgetzview Voice Calling Tablets page, where options are provided to help you select the best device for your needs.

For even more customized results, you can refine your search at the top of the page under the "Gadgetzview Calling Tablets" section. Here, you can filter choices by Popularity, Price (High to Low or Low to High), and Name. Additionally, options on the left side allow for further filtering by manufacturer, screen size, storage capacity, camera quality, RAM, battery capacity, and more. You can even set a specific price range with a sliding bar at the top of the page to narrow down options within your budget.

Apple iPad Air (2022) Wi-Fi + Cellular

Price: ₹57,999 Specifications:

Display: 10.9-inch, 2360x1640 resolution

Processor: Apple M1, octa-core

RAM: 8GB

Storage: 64GB

OS: iPadOS 15

Cameras: 12MP front and rear cameras

Dimensions: 247.6 x 178.5 x 6.1 mm, 462 grams

Colors: Blue, Pink, Purple, Space Grey, Starlight

Connectivity: USB Type-C, Wi-Fi 802.11 a/b/g/n/ac, GPS, Bluetooth

Sensors: Accelerometer, ambient light sensor, barometer, compass, gyroscope, proximity sensor

Released on March 8, 2022, the iPad Air offers high performance with an Apple M1 chip, 8GB of RAM, and a 12MP camera setup for both front and rear photography.

Apple iPad mini (2021) Wi-Fi + Cellular

Price: ₹79,900 Specifications:

Display: 8.3-inch, 2266x1488 resolution, Liquid Retina

Processor: A15 Bionic chip

Storage: 64GB

OS: iPadOS 15

Cameras: 12MP rear camera with True Tone flash, 12MP Ultra Wide front camera with Center Stage

Connectivity: Wi-Fi 6, 5G

With an upgraded Liquid Retina display and A15 Bionic chip, the iPad mini (2021) offers an enhanced performance boost, improved camera features, and is compatible with Wi-Fi 6 and 5G.

Lenovo Yoga Smart Tab

Price: ₹14,999 Specifications:

Display: 10.1-inch, 1920x1200 resolution

Processor: Qualcomm Snapdragon 439

RAM: 3GB

Storage: 32GB (expandable up to 256GB)

OS: Android 9.0 Pie

Cameras: 8MP rear, 5MP front

Battery: 7000mAh

Color: Iron Grey

Connectivity: Wi-Fi 802.11 a/b/g/n/ac, GPS, 4G

The Lenovo Yoga Smart Tab, released on September 5, 2019, provides a large display and solid battery life, featuring an expandable storage option and convenient connectivity options.

Honor Pad 5 (10.1-inch)

Price: ₹19,999 Specifications:

Display: 10.1-inch, 1920x1200 resolution, IPS

Processor: HiSilicon Kirin 659

RAM: 3GB

Storage: 32GB (expandable up to 256GB)

OS: Android Oreo with EMUI 8.0

Cameras: 8MP rear, 2MP front

Battery: 5100mAh

Color: Glacial Blue

Connectivity: Wi-Fi 802.11 a/b/g/n/ac, GPS

Released on June 11, 2019, the Honor Pad 5 is an affordable option with solid display quality and expandable storage, best suited for general multimedia use.

Samsung Galaxy Tab A 10.5 (LTE)

Price: ₹29,999 Specifications:

Display: 10.5-inch, 1920x1200 resolution

Processor: Qualcomm Snapdragon 450

RAM: 3GB

Storage: 32GB

OS: Android 8.1

Cameras: 8MP rear, 5MP front

Battery: 7300mAh

Sound: Four speakers with Dolby Atmos

The Samsung Galaxy Tab A 10.5 delivers strong battery life and immersive sound, making it a great choice for entertainment-focused users.

Xiaomi Mi Pad 4 (Wi-Fi + LTE)

Price: ₹26,999 Specifications:

Display: 8.0-inch, 1920x1200 resolution

Processor: Qualcomm Snapdragon 660

RAM: 3GB

Storage: 32GB (expandable up to 128GB)

Cameras: 13MP rear, 5MP front

Battery: 6000mAh

The Xiaomi Mi Pad 4 offers good performance with a Snapdragon 660 processor and an above-average camera, suitable for everyday use and photography.

Honor Pad 5 (8-inch)

Price: ₹16,999 Specifications:

Display: 8.0-inch, 1920x1200 resolution

Processor: HiSilicon Kirin 710

RAM: 3GB

Storage: 32GB (expandable up to 512GB)

OS: Android 9 Pie with Magic UI 2.0

Cameras: 8MP front and rear

Battery: 5100mAh

Ideal for portable use, the Honor Pad 5 (8-inch) provides a decent display and reliable performance, complemented by a user-friendly OS and expandable storage.

Li-Fi Market — Forecast(2024–2030)

Li-Fi Market Overview

The Global market for Li-Fi Market Size is forecast to reach $ 35310 Million by 2030, at a CAGR of 40.30% during forecast period 2024–2030. The market growth is attributed to the factors such as growing demand for indoor wireless communication technology in the commercial sector, increasing implementation of Li-Fi, Light as a service (LaaS) and other Optical Sensing based technology in healthcare & education sectors and others.

Moreover, rise in penetration of smart devices, construction of smart cities and commercial establishments boosts the market growth. Analysing the widespread use of LED bulbs inside buildings and the large visible light bandwidth, Li-Fi technology is much cheaper and more environmentally friendly than Wi-Fi. In many popular applications, Li-Fi technology has great potential, such as location-based services, mobile connectivity, smart lighting and hazardous environments.

Report Coverage

The report: “Li-Fi market — Forecast (2024–2030)”, by IndustryARC covers an in-depth analysis of the following segments of the Li-Fi market.

By Component type: LEDs, Optical Sensing, Photo-detectors, Microcontrollers, others

By Application: Indoor networking, Location-Based Services, Underwater communication, Smartphone, Standalone Tracker, Advance Tracker, Others

By End Users: Aerospace & Defence, Healthcare, Education, Transportation, Automotive, Consumer Electronics, Retail, Government, Others

By Geography: North America (U.S, Canada, Mexico), Europe(Germany, UK, France, Italy, Spain, Russia and Others), APAC(China, Japan India, South korea, Australia and Others), South America (Brazil, Argentina and others), and ROW (Middle East and Africa)

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Key Takeaways

As digitalisation multiplies the number of connected devices, the bandwidth of radio frequencies is facing a bottleneck due to its small capacity, which impacts the quality of service. Li-Fi technology, on the other hand, uses a visible light continuum for data processing that is free of any scale constraints. The impending RF crunch is therefore an important driver for the Li-Fi market

North America region dominated the global Li-Fi market in 2020 owing to the presence of advanced technologies, large number of manufacturers and the increasing domestic and commercial demands for Li-Fi.

Li-Fi Market Segment Analysis — By Component type

Li-Fi market is segmented into LEDs, Optical Sensing, Photo-detectors, Microcontrollers and others on the basis of component. The market of LEDs is anticipated to hold the highest market share of 48.2% in 2020 and is projected to witness fast growth. This growth can be attributed to increased LED and Light as a Service deployment at commercial establishments and industries. The ability of an LED to modulate swiftly on and off is key to Li-Fi working. These modulation and demodulation schemes transition data from one location to another.

Li-Fi operates by taking and inserting data content into an SSL driver by streaming it. This SSL driver can run a string of high speed LED lamps, turning them on and off. As the LED lamps turn on and off and strobe faster than the eye can see, it illuminates the context area. Their demand in Li-Fi systems is proliferating with several advantages of LEDs such as durability, low power consumption, and high energy output. These advantages contribute to the broad adoption of LEDs in the form of arrays for Li-Fi system infrastructure, supporting the growth of the market.

Li-Fi Market Segment Analysis — By Application type

Indoor networking type segment held the highest market share of Li-Fi in 2020. Moreover, it is anticipated to witness the significant market growth of 25.1% CAGR during the forecast period 2024–2030. Smart buildings are presently acclimatizing to accommodate their residents, in order to enhance dweller cosiness and customer experience. They do this by identifying the coordinates of each user and then providing on-site services such as smart car parking, condition monitoring, logistics and shopping support services through Light as a Service wireless communication technology. The basic idea of Li-Fi technology is to use the visible light of an LED light bulb to transmit high-speed data to a smartphone or tablet-connected photo detector and optical sensing.

Li-Fi Market Segment Analysis — By Geography

North America is anticipated to witness significant market growth of 26.7% during the forecast period 2024–2030. Market growth is attributed to factors such as technological advances, increased demand for energy-efficient appliances and increased demand for high-speed wireless connectivity technology in the area. The region also has a well-established infrastructure which allows easy implementation of advanced technologies and provides better connectivity.

North America, which has prominently taken the lead on various technological developments such as smart homes, smart cities, Internet of Things (IoT), big data and consumer electronics; has emerged as the nucleus for Li-Fi market demand. With majority of the global smart homes, intelligent transport systems and green buildings developing in the U.S., there is upliftment in the market growth of Li-Fi. In the lighting industry, the growth and increase in lifetime of LED lightening has led to the development of new commercial schematics.

Light source coming from LED bulbs provides a pathway for data in Li-Fi technology, Light as a Service and can meet any devices that it illuminates. The strobing of the LED bulb generates a signal for the receiver device, thereby transferring information. This wireless optical networking technique offers great ability to transmit data at a rate of 224 GB per second and is approximately 100 times faster than Wi-Fi.

In January 2019, VLNComm formed the industry’s fastest, most affordable, and most innovative Li-Fi LED lighting panel. The LumiNex panel, introduced and successfully demonstrated to over 500 people at CES 2018 in Las Vegas, is capable of downloading speeds of 108Mbps and upload speeds when combined with the LumiStick 2, 53Mbps. Such product launches boosts the market growth in this region.

Li-Fi Market Drivers

Inexpensive LEDs Ballooning Implementation

LED plays a vital role in the overall growth of the Li-Fi industry as a basic component of Li-Fi networks. Globally, LED is promoted due to features such as low power consumption, a lack of harmful emissions and increased lighting. Moving for the aim of ‘low carbon economy’ and ‘smart cities,’ policymakers around multiple nations are offering discounted prices for LED bulbs in order to raise application rate. Such developments increase the range of potential Li-Fi Systems users.

Adoption over Wi-Fi

Apart from potentially faster speed Li-Fi has multiple other benefits over Wi-Fi. Li-Fi offers a more secure network as light cannot pass through walls; this also minimizes the interference between devices. Li-Fi is also useful in electromagnetic sensitive areas such as in aircraft cabins, hospitals and nuclear power plants without producing electromagnetic interference. Li-Fi technology uses visible light spectrum and can thus communicate data and unravel capacity which is 10,000 times greater than that accessible within the radio spectrum. The present visible light spectrum is abundant, free and unlicensed; this will help in mitigating the radio frequency spectrum crunch effect. This will drive the Li-Fi market over the forecast period

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Li-Fi Market Challenges

Transfer within Room

Li-Fi is unable to relay the path through walls. Wi-Fi is, this drawback of Li-Fi can also be used as a protective mechanism where communication only takes place within a certain space and gadgets that are not present within the room cannot reach it.

Li-Fi Market Landscape

Partnerships and acquisitions along with product launches are the key strategies adopted by the players in the Li-Fi market. As of 2019, the market for Li-Fi market is consolidated with the top players General Electric (U.S.), Koninklijke Philips N.V. (the Netherlands), Oledcomm (France), PureLiFi Limited (U.K), Panasonic Corporation (Japan), Acuity Brands, Inc. (U.S.), LightPointe Communications, Inc. (U.S.), Velmenni (Tartu), LightBee Corporation (U.S.), FSONA Networks (U.K) and among others.

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Acquisitions/Technology Launches/Partnerships

In June 2019, Signify, the world leader in lighting, launched a new range of LiFi systems that includes the world’s fastest and most reliable LiFi systems commercially available. The range, branded Trulifi, leverages existing and future professional luminaires. Instead of using radio signals (such as WiFi, 4G/5G, Bluetooth, etc.).

In January 2019, Oledcomm announced LiFiMAX, a low-profile ceiling lamp. LiFiMax is an optical wireless communication system that offers an internet connection over light waves to up to 16 users simultaneously at a peak speed of 100Mbps.

Key Market Players:

The Top 5 companies in the Li-Fi Market are:

pureLiFi

Oledcomm

Signify (Philips Lighting)

Wipro Lighting

Panasonic Corporation

Industry trend｜Another domestic manufacturer launches new WiFi6 chip for low-power IPC

AltoBeam recently launched the new generation of Wi-Fi 6 low-power chip ATBM6461, which was independently developed and has complete intellectual property rights. The main selling point of this chip is WiFi6; the other is low power consumption. From these two functional points, it is almost tailor-made for low-power IPC.

WiFi IPC is the most important product line of consumer IPC, accounting for 80% of the market share, and 80% of them use WiFi4 transmission. As users have higher and higher requirements for image quality, interactive experience, and application scenarios, the market needs higher speed, lower power consumption, and more stable transmission technology. The development of WiFi6 technology can meet the needs of industry development. From WiFi, WiFi5 iteration to WiFi6, from single-band to dual-band, they are all in line with the trend of technology and standard iteration.

In the "2024 Visual IoT Consumer Market Analysis Report", we introduced that WiFi6 IPC has the following advantages over WiFi4 IPC:

1. High speed: WiFi6 is about 50% higher than WiFi4 of the same specification, ensuring a smooth video experience at the same distance.

2. Low power consumption: WiFi6 allows devices to plan communications with routers, reducing the time required to keep the antenna powered on to transmit and search for signals, which means reducing battery consumption and improving battery life performance. The actual power consumption is 20%~30% lower than WiFi4.

3. Stability: WiFi6 introduces cellular OFDMA technology to achieve high-density access routing, and parallel transmission is highly real-time. WiFi4 devices access routing by time-division multiplexing to grab network speed, so WiFi6 can solve the probabilistic disconnection and jamming problems of WiFi4.

4. Iteration trend of new and old standards: WiFi4 to WiFi6 is the iteration of new and old standards, similar to cellular 2G to 4G; as prices approach or remain the same, the iteration will be accelerated. At this stage, WiFi6 has the added advantage of differentiated competition with new selling points in addition to performance advantages compared to WiFi4.

On WiFi6, AltoBeam's data said: ATBM6461 supports all modes from MCS0 to MCS11 specified in the Wi-Fi6 protocol, and the physical layer supports modulation and demodulation up to 1024QAM, with a maximum bit rate of 287Mbps. At the same time, the ATBM6461 chip has further significantly improved the RF performance indicators to ensure that more data can be transmitted at a longer distance. ATBM6461 fully supports various advanced technologies in the Wi-Fi 6 protocol, such as LDPC encoding and decoding, Beamforming, Extended Range frame structure (ER-SU) and dual carrier modulation (DCM). Therefore, ATBM6461 can greatly improve the sensitivity index and the transceiver performance in complex network environments, and the signal coverage range can also be greatly increased.

In terms of low power consumption, for battery-powered terminal product applications, ATBM6461 pays special attention to optimizing the power consumption of the chip, and further extends the battery life by supporting the TWT function in the Wi-Fi6 protocol.

It is said that AltoBeam's new low-power WiFi6 product will soon be launched in the North American market. Recently, the main players in the domestic WiFi6 chip market include: Aikewei, Broadcom Integrated, Espressif Technology, Aojie Technology, etc. The "2025 Visual IOT Low Power Market Analysis Report" has started, and industry professionals are welcome to actively participate in our report. We will also include good products and good ideas in the report.

This paper is from Ulink Media, Shenzhen, China, the organizer of IOTE EXPO (IoT Expo in China)

Top Trends in Embedded Camera Module Development for Smart Devices and IoT

The rapid evolution of technology has profoundly impacted how we interact with our devices. Embedded camera modules have become essential components of smart devices and IoT applications, transforming the landscape of photography, videography, and real-time image processing. As manufacturers and developers aim to enhance functionality and user experience, several key trends are emerging in the development of these modules.

1. Miniaturization and Compact Designs

One of the most significant trends in embedded camera module development is the push toward miniaturization. Consumers increasingly demand sleek and portable devices without compromising performance. Advances in manufacturing processes, such as System-on-Chip (SoC) integration, allow for smaller camera modules that incorporate essential components like image sensors and processing units into a single package. This trend not only saves space but also reduces power consumption, making devices more efficient.

2. Enhanced Image Quality Through Advanced Sensors

As the demand for high-quality images rises, manufacturers are investing in advanced sensor technology. Recent developments in image sensors, such as the transition from CCD to CMOS technology, have drastically improved image quality, dynamic range, and low-light performance. These advancements allow for sharper images, better color accuracy, and improved performance in various lighting conditions. Additionally, features like high dynamic range (HDR) imaging are becoming standard, offering users more versatile photography options.

3. Artificial Intelligence (AI) Integration

Integrating AI into embedded camera modules is revolutionizing image processing capabilities. AI algorithms can enhance image quality, automate focus adjustments, and improve facial recognition features. This technology allows for smarter camera modules that can adapt to various environments, optimizing settings based on real-time analysis. Furthermore, AI-driven features such as object detection and scene recognition are becoming increasingly popular, providing users with enhanced functionality and creative options.

4. Increased Connectivity and Smart Features

As IoT devices proliferate, the need for seamless connectivity between devices has never been greater. Embedded camera modules are increasingly equipped with wireless connectivity options like Wi-Fi, Bluetooth, and even cellular connectivity. This allows users to instantly share images and videos across platforms or integrate their devices into broader smart home ecosystems. Additionally, features such as remote monitoring and control are becoming standard, enhancing the usability and appeal of smart devices.

5. Emphasis on Privacy and Security

With the rise of embedded cameras in various applications, privacy concerns have emerged as a significant issue. Manufacturers are taking proactive steps to address these concerns by incorporating advanced security features. Encrypted data transmission, secure boot processes, and privacy shutters are becoming standard in new camera module designs. These measures not only protect user data but also build consumer trust, making it easier for users to adopt new technologies without fear of compromising their privacy.

6. Versatile Applications Across Industries

The versatility of embedded camera modules is expanding their application across various industries. From healthcare to automotive, these modules are finding innovative uses. In healthcare, for instance, embedded cameras are utilized for remote patient monitoring, allowing healthcare providers to assess patients in real-time. In automotive applications, cameras enhance safety features such as lane departure warnings and parking assistance. This trend reflects a broader movement towards integrating smart technology into everyday life, enhancing safety, efficiency, and user experience.

7. Focus on Sustainability

As environmental concerns grow, the tech industry is responding with a focus on sustainability. Manufacturers are increasingly considering the environmental impact of their embedded camera modules by using eco-friendly materials and processes. This trend is reflected in the development of cameras that consume less power, thereby reducing their carbon footprint. Additionally, initiatives aimed at recycling and reducing electronic waste are becoming integral to product development, appealing to environmentally conscious consumers.

8. Adoption of 3D and Depth Sensing Technologies

The integration of 3D and depth-sensing technologies in embedded camera modules is another noteworthy trend. These technologies enable devices to create a three-dimensional representation of their environment, enhancing applications in augmented reality (AR) and virtual reality (VR). As AR and VR continue to gain traction in consumer markets, the demand for depth-sensing cameras will likely grow. This capability opens up new possibilities for interactive experiences in gaming, retail, and education, providing users with immersive environments.

9. Customization and Modular Designs

The trend toward customization is gaining momentum in the embedded camera module market. Manufacturers are recognizing the diverse needs of consumers and industries, leading to the development of modular camera systems. These systems allow users to select specific features and functionalities based on their requirements, such as varying resolutions, field of view, and additional functionalities like thermal imaging. This flexibility caters to a broader range of applications and user preferences, making it easier for businesses to adopt tailored solutions.

Conclusion

The landscape of embedded camera module development is evolving rapidly, driven by technological advancements and changing consumer expectations. Trends such as miniaturization, AI integration, and enhanced connectivity are reshaping how these modules function in smart devices and IoT applications. As manufacturers continue to innovate and address emerging challenges, the future of embedded camera technology holds immense potential, paving the way for smarter, more connected devices that enhance everyday life. The continuous improvement in image quality, security, and sustainability will further solidify the role of embedded cameras in the ever-growing ecosystem of smart technology. As these trends unfold, consumers can look forward to a future where their devices not only capture moments but also offer unparalleled functionality and connectivity.

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Connected Car Market Size Overview: Expected to Hit $26.4 Billion by 2030

The Connected Car Market Size is projected to reach $26.4 billion by 2030, driven by increasing demand for advanced in-car connectivity solutions and the growing adoption of smart vehicles. This rapid market growth is fueled by advancements in telematics, vehicle-to-everything (V2X) communication, and infotainment systems. As consumers demand more seamless and integrated driving experiences, automakers are increasingly incorporating connected technologies that offer real-time traffic updates, remote diagnostics, and enhanced safety features, thereby expanding the overall Connected Car Market Size.

Furthermore, the rise of autonomous driving and electric vehicles (EVs) is expected to significantly contribute to the Connected Car Market Size. Governments worldwide are supporting the development of intelligent transportation systems, which rely heavily on connected car technology to improve road safety and traffic management. Major players such as Tesla, General Motors, and BMW are continuously investing in R&D to enhance connectivity features, helping to drive growth in the connected car ecosystem and secure their positions within this expanding market.

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Cellular networks hold the fastest growing segment for the connected car market in the network segment.

Cellular connectivity, particularly 3G/4G and 5G, is being increasingly adopted by automakers for embedded and integrated connected car solutions due to several key advantages over DSRC. One of the main reasons is the ability to leverage existing cellular infrastructure, which allows automakers to utilize the already deployed network and avoid the costs of setting up dedicated DSRC hardware. This makes cellular a more cost-effective solution for connected car applications, as automakers can integrate the necessary modules into their vehicles. Another significant advantage of cellular connectivity is its improved safety and reliability. Cellular V2X (C-V2X) can provide greater capacity and lower the chance of interruptions in service, ensuring reliable communication for safety-critical applications. C-V2X also offers a more extensive communication range, enabling advanced applications like vehicle-to-home (V2H) and vehicle-to-cloud (V2C) communication. For example, Tesla has been using cellular connectivity to provide over-the-air updates and remote diagnostics for its vehicles, demonstrating the potential of cellular technology in enhancing the connected car experience.

North America is the second-largest region in the connected car market.

North America is the largest market for connected cars, driven by advanced technological infrastructure, a robust automotive industry presence, high consumer demand, and a supportive regulatory environment. Considering the vehicles sales in North America, the number of automobiles sold in the US rose from 14.4 million in 2022 to 16.1 million in 2023, in which premium automobile sales (E, F, and SUV - E) category sales went from 1.6 million in 2022 to 1.8 million in 2023, a rise of ~12.1%. Additionally, D-segment car sales in the US rose by 4% from 4.1 million units in 2022 to 1.5 million units in 2023. Improved cellular V2X systems, telematics systems, dynamic route optimisation, in-car Wi-Fi and internet access, and over-the-air software upgrades for sedans and premium vehicles are just a few of the technologies available in these high-end cars.

Key Players

Major manufacturers in the connected car market include Continental AG (Germany), Robert Bosch GmbH (Germany), Harman International (US), Airbiquity (US), and Visteon (US).

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Integration of Smart Pushbutton Switches and Remote Control Technology: Driving Smart Manufacturing in Industry 4.0

With the rapid development of Industry 4.0 and the Internet of Things (IoT), traditional pushbutton switches are evolving towards intelligence. Smart pushbutton switches not only perform basic switching functions but also incorporate advanced technologies such as remote monitoring, automated control, and data communication. These smart pushbutton switches play a critical role in factory automation and smart manufacturing systems, meeting the growing demand for remote control while ensuring compatibility with industrial communication protocols (e.g., Modbus, Profinet), laying the foundation for comprehensive integration in Industry 4.0.

1. Integration Technology of Smart Pushbutton Switches

Smart pushbutton switches are a combination of traditional mechanical buttons and modern electronic technology. In addition to providing physical actuation, they integrate sensors, microprocessors, and communication modules to enable real-time monitoring, data collection, and remote control.

1.1 Internal Integration of Circuits and Sensor Technology Smart pushbutton switches feature built-in microcontrollers (MCUs) and sensors that allow real-time sensing of switch states and transmit data to cloud platforms or local management systems. For example, buttons can integrate pressure sensors, temperature sensors, or vibration sensors to monitor the operational status and environmental conditions of equipment.

Application Example: During an industrial manufacturing process, a pushbutton switch with an integrated temperature sensor can monitor equipment's temperature changes in real time. If the temperature exceeds a set threshold, the switch automatically sends an alert and controls the equipment to stop, preventing damage caused by overheating.

1.2 Data Collection and Communication Module Integration Smart pushbutton switches can also integrate wireless communication modules (e.g., Wi-Fi, Zigbee, or LoRa) to send collected data to remote servers. These switches are not limited to local operation but can be tracked in real-time through remote monitoring platforms, leveraging big data analysis to optimize production processes.

2. Remote Monitoring and Control of Smart Pushbutton Switches

In smart manufacturing environments, remote monitoring and control functions significantly enhance factory management efficiency. Traditional pushbutton switches require manual on-site operation, whereas smart pushbutton switches can achieve remote control via network connectivity, supporting automated management and reducing manual intervention.

2.1 Implementation of Remote Control Through wireless communication technology, smart pushbutton switches can connect with central control systems or mobile devices, enabling operators to remotely control switches through computers or smartphone applications. Smart switches can integrate with factory automation systems (e.g., SCADA systems) to provide real-time remote control and status monitoring of production equipment.

Application Example: In a large factory, smart pushbutton switches are used to remotely control the start and stop of machines. When a fault is detected on a production line, the factory manager can remotely shut down the related equipment from the control center or mobile app, minimizing production accidents and downtime.

2.2 Real-Time Data Feedback and Alarm Functions Smart pushbutton switches are capable not only of remote control but also real-time data feedback and alarm functions. When the switch detects an abnormal condition (e.g., overload, temperature anomaly, or circuit fault), the system immediately sends an alert to notify the management. Through the remote monitoring system, operators can quickly identify and resolve the issue, minimizing the impact of equipment failures.

Application Example: A manufacturing company’s smart pushbutton switch system monitors the electrical current of equipment in real time. If the current exceeds a safe range, the smart switch immediately cuts off the power and sends an alert, preventing potential overheating or burning of equipment.

3. Compatibility Design of Pushbutton Switches with Industrial Communication Protocols

In industrial automation, pushbutton switches play a crucial role as input devices. They must be compatible with various industrial communication protocols to seamlessly integrate into existing industrial control systems, such as PLC (Programmable Logic Controller) networks and Distributed Control Systems (DCS). Modbus, Profinet, and similar protocols are the core standards for industrial communication, and smart pushbutton switches need to be designed for seamless integration with these protocols.

3.1 Modbus Protocol Compatibility Design Modbus is a widely used protocol for communication between industrial devices, typically facilitating data transmission between PLCs and controllers. Smart pushbutton switches with built-in communication modules compatible with Modbus protocol can directly exchange data with PLCs. This allows the switches to perform not only simple switching operations but also bidirectional communication with device management systems, enabling remote status monitoring and parameter adjustments.

Application Example: In a factory, a smart pushbutton switch is connected to a PLC via Modbus, allowing real-time feedback of the switch status. Factory managers can adjust the switch's response parameters through the control system to optimize its sensitivity and operation.

3.2 Profinet Protocol Compatibility Design Profinet is an industrial Ethernet-based standard used for efficient real-time communication, especially in scenarios requiring high response speeds. By supporting the Profinet protocol, smart pushbutton switches can integrate seamlessly with fieldbus and control networks, providing fast and reliable responses.

Application Example: In an automated production line, smart pushbutton switches connect to the robotic control system via Profinet, enabling real-time control and feedback of multiple devices on the production line. Through the Profinet network, switch state changes can be transmitted to the control center within milliseconds, ensuring quick responses during the production process.

4. Application Prospects of Smart Pushbutton Switches in Industry 4.0

The integration and remote control technologies of smart pushbutton switches lay a solid foundation for Industry 4.0’s smart manufacturing. By integrating sensors and communication technology, pushbutton switches can play a more intelligent role in factory automation control.

4.1 Data-Driven Intelligent Decision-Making Smart pushbutton switches are not just operational interfaces but also sources of valuable data for smart manufacturing. These data can be used for production forecasting, equipment maintenance, and energy efficiency optimization. For example, data collected by smart pushbutton switches allow companies to analyze the status of equipment, predict potential failures, and conduct maintenance in advance, reducing unplanned downtime.

Application Example: A factory monitors real-time data from pushbutton switches to accurately predict maintenance times for production line equipment, preventing interruptions caused by equipment failure and improving overall operational efficiency.

4.2 Integration with Cloud Computing and Big Data Combining smart pushbutton switches with cloud computing and big data platforms enables broader remote management and optimization. Through cloud platforms, operators can not only monitor equipment status remotely but also use data analytics to identify potential issues and improvement opportunities.

Application Example: In a globalized production network, smart pushbutton switches connected to a cloud platform allow for remote management across different regions. Factory managers can monitor equipment operation in real-time across various facilities and make adjustments remotely.

5. Future Development Trends of Smart Pushbutton Switches

As IoT and smart manufacturing continue to spread, smart pushbutton switches will become even more intelligent and multifunctional. The following are key trends in the future development of smart pushbutton switches:

5.1 Application of Artificial Intelligence (AI) Technology By introducing AI algorithms into smart pushbutton switches, devices will be able to learn and optimize their operations autonomously. For example, smart switches may adjust their sensitivity based on usage habits or automatically modify control strategies by analyzing environmental data.

5.2 Introduction of Edge Computing Technology Future smart pushbutton switches will leverage edge computing technology to process more data locally, reducing reliance on remote servers. This will enhance system response speed and improve the autonomous decision-making capabilities of pushbutton switches.

Conclusion

The integration and remote control technologies of smart pushbutton switches are revolutionizing industrial manufacturing. Through compatibility with industrial communication protocols, smart pushbutton switches can seamlessly integrate into industrial automation systems, enabling real-time control and remote monitoring. In the future, with the introduction of artificial intelligence and edge computing technologies, smart pushbutton switches will play an even more crucial role in Industry 4.0, driving manufacturing towards greater intelligence and automation.

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Wi-Fi 7 Market Detailed Analysis and Forecast 2024–2030

The Wi-Fi 7 Market was valued at USD 1.1 billion in 2023 and will surpass USD 22.3 billion by 2030; growing at a CAGR of 53.7% during 2024 - 2030. The digital landscape is ever-evolving, and as our reliance on wireless technology grows, so does the need for faster, more reliable internet connections. Enter Wi-Fi 7, the latest standard in wireless technology, promising to revolutionize how we connect to the internet.

Wi-Fi 7 is designed to meet the demands of the increasingly connected world, offering enhanced speed, lower latency, and greater capacity. It operates in the 2.4 GHz, 5 GHz, and 6 GHz frequency bands, just like Wi-Fi 6E, but it introduces several key innovations:

Increased Bandwidth: Wi-Fi 7 supports channel widths of up to 320 MHz, double the 160 MHz available in Wi-Fi 6. This means faster data rates, which could reach up to 46 Gbps under ideal conditions.

Multi-Link Operation (MLO): This feature allows devices to transmit data across multiple bands simultaneously, reducing latency and increasing reliability. This is particularly beneficial for applications like online gaming, virtual reality (VR), and augmented reality (AR), where low latency is crucial.

1024-QAM and Beyond: Wi-Fi 7 introduces 4096-QAM (Quadrature Amplitude Modulation), up from 1024-QAM in Wi-Fi 6. This enhances the efficiency of data transmission, resulting in faster speeds.

Improved Spatial Streams: Wi-Fi 7 can support up to 16 spatial streams, compared to 8 in Wi-Fi 6, which significantly enhances throughput and network efficiency, particularly in dense environments.

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Market Outlook for Wi-Fi 7

The global Wi-Fi 7 market is anticipated to grow rapidly as the demand for high-speed internet and low-latency connections continues to surge. Several factors are driving this growth:

Increasing Demand for High-Bandwidth Applications: As more devices are connected to the internet, from smartphones and laptops to smart home devices and industrial IoT applications, the need for faster, more reliable Wi-Fi becomes critical. Wi-Fi 7's enhanced capabilities make it an ideal solution for these high-bandwidth applications.

Enterprise Adoption: Businesses are increasingly adopting advanced technologies like cloud computing, AI, and machine learning, all of which require robust and reliable internet connections. Wi-Fi 7's ability to deliver high-speed, low-latency connections will be crucial for supporting these technologies, making it a key driver for enterprise adoption.

Smart Homes and IoT: The smart home market is booming, with more devices than ever connected to home networks. Wi-Fi 7's ability to handle multiple devices simultaneously without compromising performance will be a significant advantage in this sector.

Telecommuting and Remote Work: The COVID-19 pandemic has accelerated the trend toward remote work, increasing the demand for reliable home internet connections. Wi-Fi 7 can provide the speed and reliability needed for seamless video conferencing, file sharing, and other remote work activities.

Challenges in the Wi-Fi 7 Market

Despite its promising potential, the Wi-Fi 7 market faces several challenges:

Cost of Implementation: Upgrading to Wi-Fi 7 will require new hardware, including routers and devices capable of supporting the new standard. This could be a significant investment for both consumers and businesses, potentially slowing adoption rates.

Compatibility and Interoperability: As with any new technology, ensuring compatibility with existing devices and networks is a challenge. Manufacturers will need to work together to ensure seamless interoperability across different devices and platforms.

Spectrum Availability: Wi-Fi 7 operates on the 6 GHz band, which is not yet available worldwide. Regulatory approval for this spectrum in different regions will be critical for the global adoption of Wi-Fi 7.

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Conclusion

Wi-Fi 7 represents a significant leap forward in wireless technology, offering the speed, capacity, and reliability needed to support the next generation of internet-connected devices and applications. While there are challenges to its widespread adoption, the benefits it brings to both consumers and enterprises are undeniable. As the market continues to evolve, Wi-Fi 7 is set to play a pivotal role in the future of wireless connectivity, driving innovation and enabling new possibilities in our increasingly digital world.

AdLink I-Pi SMARC 1200 Plus DevKit With MediaTek Genio 1200

I-Pi SMARC 1200

AdLink I-Pi SMARC 1200 Plus DevKit, an octa-core MediaTek Genio 1200 processor-powered AI and graphics-focused solution. The octa-core Arm Cortex-A78 and Cortex-A55 CPUs in the Genio 1200 are paired with a 5-core Arm Mali-G57 GPU for cutting-edge 3D graphics and an embedded NPU that can handle up to 5 TOPS of edge AI data.

The on-device AI processing capabilities of the I-Pi SMARC 1200 include computer vision and deep learning neural network acceleration. Moreover, up to three MIPI camera inputs and several 4K displays are supported by the SMARC. For a variety of next-generation AI focused developments, including smart homes, industrial IoT, 3K multimedia apps, and human-machine interfaces, this is the go-to option. Product developers can explore new avenues and expedite proof of concept creation before production with the dev kit, which lowers costs and shortens time to market.

Pi SMARC 1200

MediaTek Genio 1200 platform

The Octa-core MediaTek MT8395 powering the LEC-MTK-I1200 module (Cortex-A78 x4 + A55 x4 in the arm)

The Smart Mobility Architecture, or SMARC Form Factor

SMARC 2.1 specification: a very small and power-efficient design appropriate for edge computing and embedded applications.

Due to its small size (82 x 80 mm), it is perfect for designs that need to save space, like industrial IoT systems, robotics, smart home appliances, and AI cameras.

All-encompassing Connectivity

Support for Bluetooth 5.2 and Wi-Fi 6 allows for fast wireless data transfer.

Support for optional 5G: Enables cellular high-speed connectivity for Internet of Things applications that need dependable network access.

Gigabit Ethernet: Quick connectivity for edge devices via wired networks.

Display and Graphics

Equipped with a Mali-G57 GPU, capable of encoding and decoding 4K60 HDR video.

There are several display interfaces available for connecting high-definition monitors and displays, including as HDMI, eDP, and MIPI DSI.

A Variety of I/O Interfaces

Peripheral connectivity via PCIe, USB 3.1, and I2C enables expansion with extra parts including cameras, sensors, and storage devices.

AI cameras can be connected via the MIPI CSI camera interface, which is helpful for robotics and smart surveillance applications.

AI & Machine Learning on the Edge

For real-time decision-making, the AI Processing Unit reduces dependency on cloud computing by enabling effective AI inferencing at the edge.

Perfect for jobs involving natural language processing, computer vision, and machine learning.

Stored Information and Memory

Supports high-speed memory operations with LPDDR4x RAM.

Sffers external SD card ports, UFS, and eMMC as storage options.

Low Power Need

It is appropriate for battery-powered IoT devices such as smart cameras, portable robotics, and IoT sensors because it was designed with energy efficiency in mind.

Uses in Industry

Suitable for industries where AI and IoT solutions are essential, such as smart manufacturing, smart cities, healthcare, and retail.

Creation and Personalization

Offers compatibility for Linux, Android, and other embedded operating systems together with a thriving software ecosystem.

Gives developers the ability to design unique apps and solutions for AI-powered Internet of Things gadgets.

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AGV links MES to Create Intelligent Warehousing System 1--How to use ARM Embedded Computer to build AGV System?

What is AGV (Automated Guided Vehicle) ?

AGV (Automated Guided Vehicle) can generally control its route and behavior through a computer. It has strong self-adjustment, high degree of automation, accuracy and convenience, can effectively avoid human errors and save human resources. In the automated logistics system, rechargeable batteries are used as the power source to achieve flexibility, efficient, economical and flexible unmanned work and management.

Types of AGV Vehicle Controllers

The vehicle controller is the core of the control system and even the entire AGV. The vehicle controllers used by AGV are basically divided into the following three types:

PLC：PLC has the advantages of high reliability, easy programming, and flexible expansion, and is suitable for most AGV application scenarios. However, PLC also has disadvantages such as high cost and large size.

ARM Industrial Computer：ARM Embedded Computer is actually a computer with powerful computing power and flexible expansion capabilities. It has strong anti-interference capabilities and can be used in harsh industrial environments such as vibration and electromagnetic radiation. ARM Embedded Computer has a compact structure and small size, and can run general operating systems such as Linux.

Microcontroller：The advantages of microcomputers include low cost, low power consumption, and small size, making them suitable for small and medium-sized, cost-sensitive AGV applications. However, the shortcomings of microcomputers, such as limited computing power and limited storage space, also limit their scope of application.

The Composition of AGV

Traditional AGV system

Traditional AGV systems mainly rely on PLC, IO modules, switches, 4G routers and other devices to work together.

PLC as control center: responsible for receiving data from sensors and controlling the actions of AGV according to preset logic.

IO module: used to connect various sensors and actuators to realize signal conversion and transmission.

Switch: ensure smooth communication between various components.

4G router: provides connection with external systems to realize remote monitoring and data exchange.

Although traditional systems can meet basic automation needs, they have some obvious limitations:

High hardware cost: multiple independent devices need to cooperate with each other to achieve complete functions.

Complex maintenance: The complexity of the system leads to high maintenance costs and high requirements for the expertise of technicians.

Difficult expansion: adding new functions or changing existing settings is cumbersome, which limits the flexibility of the system.

AGV System based on ARM Embedded Computer ARMxy

Powerful computing power: ARMxy Embedded Computers are equipped with high-performance processors, which can easily cope with complex control algorithms, multi-sensor data fusion, and real-time path planning. Integrated AI function support can achieve more complex and efficient path planning and task scheduling.

Rich interfaces: ARMxy Embedded Computers provide a variety of optional interfaces, such as serial ports, Ethernet, CAN ports, IO module ports, etc., which can be easily connected to various sensors, actuators, etc. according to actual conditions.

Efficient communication: ARMxy Embedded Computers support multi-channel CAN bus interfaces, 4G/5G and Wi-Fi technologies to ensure real-time data exchange between AGV and WMS(Warehouse management system), MES（Manufacturing execution system） and cloud platforms.

Flexible scalability: ARMxy Embedded Computers support a variety of operating systems and development environments, and can flexibly configure and expand system functions according to needs, facilitating users to carry out secondary development.

High reliability: ARMxy Embedded Computers usually use industrial-grade components, have high reliability and stability, and can adapt to harsh industrial environments.

Support multi-tasking: ARMxy Embedded Computers can run multiple tasks at the same time to achieve multiple control functions for AGV.

Comparative Analysis

Compared with the traditional AGV system, the new system based on ARMxy Embedded Computers has the following obvious advantages:

Cost-effectiveness: It reduces the need for multiple independent devices, and reduces hardware and installation costs. The low power consumption and small size of ARMxy Embedded Computers make AGV control more compact.

Hardware integration: ARMxy Embedded Computers integrate functions such as PLC, IO modules and network communication, reducing the need for additional hardware.

Low maintenance cost: ARMxy Embedded Computers have low power consumption, small size, and highly integrated design, which simplifies the maintenance process of the system and reduces maintenance costs.

Flexibility: The highly integrated ARMxy Embedded Computers makes it easier for the system to adapt to changes in the production line.

Rich interfaces: RS485/RS232, Ethernet, CAN, RS485/RS232, GPIO, DI/DO/AI/AO, etc. are optional. They can be freely combined without customization. They can easily connect various sensors, actuators and other devices.

Quick response: It can adapt to changes in production plans more quickly and improve the flexibility of the production line.

Remote management: It supports remote monitoring and management, reducing the need for on-site intervention.

Intelligent features: With the support of integrated AI functions, more complex and efficient path planning and task scheduling can be achieved.

Machine learning algorithm: Optimize path planning through machine learning algorithms to improve work efficiency and accuracy.

Data analysis: Analyze the collected data to continuously improve the performance of the AGV system.

Real-time communication: The application of wireless communication technology enables AGV to achieve real-time data exchange with external systems.

Data synchronization: It can synchronize the working status and performance indicators of AGV in real time, which is convenient for scheduling and maintenance.

Remote access: Support remote access and control, which improves the accessibility and availability of the system.

More information about ARMxy Embedded Computers: https://www.bliiot.com/industrial-computer-p00464p1.html

General Electric PBX23W00Y0 SmartHQ Connect Module HnKParts

Manufacturer Name: GENERAL ELECTRIC Product Number: PBX23W00Y0 OEM Part Number: PBX23W00Y0 Product Description: U+ Connect Module

The U+ Connect Module For General Electric Pbx23w00y0 is an add-on for dishwashers that enables smart functions. It plugs into your dishwasher and connects to your home's Wi-Fi network. Once connected, the module enables you to manage and monitor the dishwasher remotely via an app for your smartphone.

Industrial IoT Edge Gateway: Enhancing Industrial Automation with Creative Micro Systems

In the era of Industry 4.0, Industrial IoT (IIoT) is revolutionizing the way industries operate, providing unprecedented levels of connectivity and intelligence. At the heart of this transformation lies the Industrial IoT Edge Gateway, a crucial component that bridges the gap between industrial equipment and the cloud. Creative Micro Systems is leading the charge with state-of-the-art IIoT edge gateway solutions designed to enhance industrial automation and drive operational efficiency. This article explores the significance of Industrial IoT edge gateways and how Creative Micro Systems is pioneering in this space.

Understanding Industrial IoT Edge Gateways

An Industrial IoT edge gateway is a device that collects, processes, and transmits data from various industrial sensors and machines to the cloud or central data repository. These gateways serve as the intermediary, enabling real-time data processing at the edge of the network, which is critical for time-sensitive applications and minimizing latency.

Key Features of Industrial IoT Edge Gateways

1. Real-Time Data Processing

Edge gateways process data locally, ensuring real-time analysis and decision-making. This capability is essential for applications that require immediate responses, such as predictive maintenance and quality control. Creative Micro Systems’ edge gateways are equipped with powerful processors that handle vast amounts of data efficiently.

2. Robust Connectivity

Industrial environments often require robust and reliable connectivity options. Creative Micro Systems’ edge gateways support multiple communication protocols, including Ethernet, Wi-Fi, LTE, and IoT-specific protocols like MQTT and OPC-UA, ensuring seamless integration with existing infrastructure.

3. Enhanced Security

Security is paramount in industrial applications. Creative Micro Systems incorporates advanced security features in their edge gateways, such as encryption, secure boot, and hardware-based security modules, to protect sensitive industrial data from cyber threats.

4. Scalability and Flexibility

Industries require scalable and flexible solutions to accommodate evolving needs. Creative Micro Systems’ edge gateways are designed to support modular expansions and can be easily integrated with various industrial systems, making them ideal for a wide range of applications.

5. Edge Intelligence

By integrating AI and machine learning capabilities, Creative Micro Systems’ edge gateways provide intelligent insights at the edge. This edge intelligence enables predictive analytics, anomaly detection, and optimized operational efficiencies without relying solely on cloud processing.

Applications of Industrial IoT Edge Gateways

1. Predictive Maintenance

Edge gateways play a pivotal role in predictive maintenance by monitoring equipment health in real-time. By analyzing data such as vibration, temperature, and usage patterns, Creative Micro Systems’ edge gateways predict potential failures before they occur, reducing downtime and maintenance costs.

2. Process Optimization

Real-time data processing at the edge enables industries to optimize their processes dynamically. Creative Micro Systems’ edge gateways facilitate immediate adjustments based on data analytics, improving efficiency and productivity in manufacturing, energy management, and other industrial operations.

3. Quality Control

Ensuring product quality is crucial in industrial production. Creative Micro Systems’ edge gateways analyze data from sensors and machines to detect deviations from quality standards instantly, allowing for immediate corrective actions and maintaining high-quality output.

4. Asset Tracking

Edge gateways enhance asset tracking by providing real-time visibility into the location and status of assets. Creative Micro Systems’ solutions ensure efficient asset management, reducing losses and improving operational efficiency in logistics and supply chain management.

Benefits of Using Creative Micro Systems’ Industrial IoT Edge Gateways

Increased Efficiency

By processing data locally and reducing latency, Creative Micro Systems’ edge gateways enable faster decision-making and improved operational efficiencies.

Cost Savings

Edge gateways reduce the need for constant data transmission to the cloud, lowering bandwidth costs and enabling cost-effective scalability.

Enhanced Reliability

With robust connectivity and advanced security features, Creative Micro Systems’ edge gateways ensure reliable and secure operations in demanding industrial environments.

Future-Proof Solutions

Creative Micro Systems designs edge gateways with scalability and flexibility in mind, ensuring that industries can adapt to future technological advancements and evolving business needs.

Conclusion

The Industrial IoT edge gateway is a cornerstone of modern industrial automation, providing real-time data processing, robust connectivity, and enhanced security. Creative Micro Systems is at the forefront of this technological revolution, offering innovative edge gateway solutions that drive efficiency, reduce costs, and improve operational reliability. As industries continue to embrace IoT and digital transformation, Creative Micro Systems’ Industrial IoT edge gateways will play a crucial role in shaping the future of industrial automation, enabling smarter, more connected, and more efficient industrial operations.