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nonstandardrepertoire · 5 months ago

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Parashat Yitro: אָנֹכִי | anokhi

I sometimes try to imagine myself at scale, fitting myself in to the largest space I can comprehend. I’ll start with holding the entire room I’m in in my head, then the entire building, then the street, the neighborhood, the city, stretching my awareness out and out to the nearest coastline, the nearest ocean, the great grand curvature of the Earth. I usually cannot get very far before my head starts swimming, before the smallness of me and the hugeness of this so so tiny planet overwhelm me and splay me out like so much insubstantial nothing.

[A short one this week, and probably again for the next few weeks. If you know, you know.]

In Shəmot 20:15, we read: וַיַּֽרְא הָעָם וַיָּנֻֽעוּ וַיַּעַמְדוּ מֵרָחֹק | vayár ha’am vayanú’u vaya’amdu meiraḥoq | “the people feared and wavered and stood at a distance” during the theophany at Sinai.

One might ask: How much of the theophany did they actually experience before pulling back from the mountain?

Rabbi Naftali Zvi Horowitz of Ropshitz (1760–1827) says that his teacher, Rabbi Menachem Mendel of Rimanov (1745–1815), suggested שֶׁאֶפְשַׁר שֶׁלֹּא שָׁמַֽעְנוּ מִפִּי הַקָּדֹשׁ בָּרוּךְ הוּא רַק אוֹת א דְּאָנֹכִי | she’efshar shelo shamánu mipi haqadosh barukh hu raq ot alef də’anokhi | “that we [a] heard nothing from the mouth of the Holy Blessed One other than the letter alef of ‘anokhi’ [the first word of the first commandment]” [b].

[a] I have not spent a lot of time with this text, but I assume that R' Horowitz writes “we” instead of “they” here in reference to the tradition that every Jew who ever was or will be was at Sinai — that Torah was revealed to all of us in all times, not just the generation of the Exodus. [b] I am not 100% sure how to cite this text properly. On Sefaria, it’s included as section 13 of the Shavu’ot chapter of the Festival part of Zera Kodesh, but I’ve seen other people cite it more simply as “Zera Kodesh 2.40”. Hopefully that’s enough for you to track down the original if you want to.

Alef is a glottal stop; it makes no noise. It is the absence of noise, the cessation of breath. How can one hear this?

We read earlier in Shəmot 20:15: וְכׇל־הָעָם רֹאִים אֶת־הַקּוֹלֹת | vəkhol ha’am ro’im et haqolot | “And all the people see the thunder” — from this we know revelation is a moment where the senses commingle, where hearing and seeing and otherwise experiencing are not necessarily distinguished.

We know from Bəreishit 1:2 that before there can be creation, G-d’s breath must be free to move, to blow across the primordial waters, to carve out the small cosmological bubble in which all earthly life exists. We know from the blessing for morning light that creation is never complete, that it is renewed daily by constant action from G-d. When G-d’s breath is interrupted, creation unbecomes.

Alef, in gematria, has a value of one. At Sinai, we heard this alef; we experienced one. And not just any one, but the absolute, all-encompassing One of G-d. We were, for the flick of a glottis, united wholly with G-d, experiencing and being simultaneously all things, all places, all times.

Imagine doing this with the whole entire universe.

To lose all distinctions between self and not-self is a form of oblivion, a kind of death. A human cannot interface with G-d directly and survive. No wonder we begged for Mosheh to bear the terrible burden of being plunged into this incomprehensible unity in our stead.

Revelation is at hand, but who can stand to receive it?

[This has been an installment of One-Word Torah. You can read the full series here.]

#one-word Torah #Torah commentary #parashat Yitro #yitro #parashat hashavu’a #Jumblr #Sinai theophany

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szonikuscsavarhuzo · 2 years ago

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Megjelent az új Raspberry

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Broadcom BCM2712 2.4GHz quad-core 64-bit Arm Cortex-A76 CPU, with cryptography extensions, 512KB per-core L2 caches and a 2MB shared L3 cache

VideoCore VII GPU, supporting OpenGL ES 3.1, Vulkan 1.2

Dual 4Kp60 HDMI® display output with HDR support

4Kp60 HEVC decoder

LPDDR4X-4267 SDRAM (4GB and 8GB SKUs available at launch)

Dual-band 802.11ac Wi-Fi®

Bluetooth 5.0 / Bluetooth Low Energy (BLE)

microSD card slot, with support for high-speed SDR104 mode

2 × USB 3.0 ports, supporting simultaneous 5Gbps operation

2 × USB 2.0 ports

Gigabit Ethernet, with PoE+ support (requires separate PoE+ HAT)

2 × 4-lane MIPI camera/display transceivers

PCIe 2.0 x1 interface for fast peripherals (requires separate M.2 HAT or other adapter)

5V/5A DC power via USB-C, with Power Delivery support

Raspberry Pi standard 40-pin header

Real-time clock (RTC), powered from external battery

Power button

#raspberry pi 5 #Youtube

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adafruit · 2 years ago

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we love a colorbar, oh oh oh oh!

red, orange, yellow, green, blue… we love a rainbow when it appears on our TFT display! there's three parts to getting these funky displays working with raspberry pi over the DSI port: the SPI configuration of the screen, the I2C configuration of the ICN6211 converter and the DTO device tree overlay on the pi itself. all must be perfect for an image to appear! to make it less complex, we're going to only do one part at a time and celebrate the successes. we already got the SPI config working - blinking all the pixels on and off - now we look at the ICN configuration - to make sure the PLL and resolution and sync's are correct! in order to separate it from the raspi MIPI DSI interface config, we turn on BIST test mode and have it display a colorbar. if the colors are in the right order we know that we have 2 out of 3 working, and we can move onto the next stage…Device Tree Overlay config!

#adafruit #electronics #opensource #manufacturing #opensourcehardware #raspberry pi

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bitstream24 · 2 years ago

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Linux Micro Development Board, Integrates ARM Cortex-A7/RISC-V MCU/NPU/ISP Processors

The LuckFox Pico represents a cost-effective Linux micro development board based on the Rockship RV1103 chip, which supplies a straightforward and efficient development platform for embedded system designers. It supports a variety of interfaces, including MIPI CSI, GPIO, UART, SPI, I2C, USB, and more. Developing applications is convenient, and debugging is quick.

#linux #embedded software #embedded systems #embedded computer #arm cortex

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sincerefirst-aiotmodule · 7 days ago

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SF-SCWV13M-XK-A2 IMX258 MIPI Camera Module

We are SincereFirst, a top - tier provider of camera modules. There is IMX258 sensor camera modules with new design: featuring MIPI interface and built - in LED. Fixed Focu, match DFOV117 lens. Let's talk about how our camera modules can meet your project request.

GUANGZHOU SINCERE INFORMATION TECHNOLOGY LTD. Attn.: Ms. Annie Skype/E-mail: [email protected] M.B/Whatsapp:+8617665309551 Sincere Eco-Industrial Park, GuanNanYong Industrial Zone, GZ

#youtube #camera module

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komalllsinhh · 9 days ago

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HD Video Chip Market : Size, Share Growth, SWOT Analysis, Key Players, Industry Trends and Regional Outlook

Global HD Video Chip Market Research Report 2025(Status and Outlook)

The global HD Video Chip market size was valued at US$ 12.4 billion in 2024 and is projected to reach US$ 19.8 billion by 2032, at a CAGR of 6.9% during the forecast period 2025-2032.

HD video chips are specialized integrated circuits designed to process, encode, decode, and transmit high-definition video signals across various interfaces. These chips support multiple video formats including HDMI, DisplayPort, MIPI, and others, enabling seamless connectivity between devices with different interface standards. The market includes two primary product categories: external video interface chips (for device-to-device connections) and internal video interface chips (for intra-device signal routing).

The market growth is primarily driven by increasing demand for high-resolution displays across consumer electronics, automotive infotainment systems, and industrial monitoring applications. The proliferation of 4K/8K content and adoption of advanced display technologies like OLED and MicroLED are creating new opportunities. However, supply chain constraints in semiconductor manufacturing pose temporary challenges. Key players such as Texas Instruments and Analog Devices are investing heavily in next-generation video processing technologies, with recent developments including AI-accelerated real-time video enhancement capabilities integrated into their latest chip designs.

Our comprehensive Market report is ready with the latest trends, growth opportunities, and strategic analysis. https://semiconductorinsight.com/download-sample-report/?product_id=48075

Segment Analysis:

By Type

External Video Interface Segment Leads Due to Rising Demand for High-Quality Display Solutions

The market is segmented based on type into:

External Video Interface

Subtypes: HDMI, DisplayPort, USB-C, and others

Internal Video Interface

Subtypes: LVDS, V-by-One, and others

Others

By Application

Consumer Electronics Segment Dominates with Increasing Adoption of 4K/8K Displays

The market is segmented based on application into:

Consumer Electronics

Subtypes: Smart TVs, Gaming Consoles, and others

Automotive Electronics

Industrial

Security Monitoring

Others

By End User

OEMs Segment Holds Major Share Due to Direct Integration in Device Manufacturing

The market is segmented based on end user into:

Original Equipment Manufacturers (OEMs)

Aftermarket

System Integrators

Others

Regional Analysis: Global HD Video Chip Market

North America The North American HD video chip market is characterized by strong demand driven by advancements in consumer electronics, automotive displays, and industrial automation. The region benefits from robust R&D investments by key players such as Texas Instruments and Analog Devices, Inc., particularly in high-bandwidth interfaces like HDMI 2.1 and DisplayPort 2.0. The U.S. dominates the market, supported by widespread 4K/8K TV adoption and stringent quality standards. However, supply chain disruptions and semiconductor shortages have impacted production timelines, leading to occasional price volatility. The growing popularity of AR/VR applications and smart surveillance systems is further propelling demand for high-performance video processing chips.

Europe Europe’s market thrives on innovation and strict regulatory frameworks for video quality and energy efficiency. Countries like Germany and France are at the forefront, leveraging HD video chips for automotive infotainment systems and industrial IoT. The EU’s emphasis on green electronics encourages chip manufacturers to develop low-power solutions without compromising performance. Major collaborations between automotive OEMs and semiconductor firms, such as those seen in Tesla and BMW’s dashcam integration, exemplify this trend. However, geopolitical tensions and dependence on Asian foundries pose challenges for regional supply chain stability. The rise of telemedicine and video conferencing post-pandemic has also sustained demand.

Asia-Pacific As the largest consumer and producer of HD video chips, Asia-Pacific is driven by China’s manufacturing prowess and India’s burgeoning electronics sector. Companies like Toshiba and Lontium Semiconductor dominate production, catering to global demand for smartphones, TVs, and surveillance equipment. Southeast Asian nations are emerging as assembly hubs due to cost advantages, though intellectual property concerns persist. The region’s rapid urbanization fuels adoption of 4K security cameras and automotive ADAS systems. Nevertheless, trade restrictions and fluctuating raw material costs occasionally disrupt market growth. Consumer electronics, particularly gaming consoles, remain the primary revenue generator.

South America South America’s market is nascent but growing, with Brazil leading in digital TV transitions and smart city initiatives. Local manufacturing is limited, prompting reliance on imports from North America and Asia. Economic instability and currency devaluation hinder widespread adoption of premium video chips, though sectors like broadcasting and surveillance show consistent demand. Government investments in public safety infrastructure have spurred interest in HD-compatible chips, but budget constraints slow procurement. The lack of domestic semiconductor fabrication units remains a critical bottleneck for regional market expansion.

Middle East & Africa The MEA market is uneven, with growth concentrated in GCC countries and South Africa. Demand stems from oil & gas monitoring systems, luxury automotive displays, and hospitality AV solutions. The UAE’s focus on smart city projects, such as Dubai’s 5G-enabled surveillance networks, drives niche opportunities. In contrast, African nations face infrastructure gaps, limiting HD chip penetration to urban centers. Partnerships with Chinese tech firms are bridging this divide by offering cost-effective solutions. Long-term potential lies in telecommunications and educational tech, though political instability and low disposable incomes restrict immediate growth.

List of Key HD Video Chip Companies Profiled

Texas Instruments (U.S.)

Parade Technologies (Taiwan)

Toshiba Electronic Devices & Storage Corporation (Japan)

Lontium Semiconductor Corporation (China)

Analog Devices, Inc. (U.S.)

Analogix Semiconductor (U.S.)

ITE Tech. Inc. (Taiwan)

Algoltek, Inc. (Taiwan)

The global market for high-definition video chips is experiencing robust growth, primarily driven by the accelerating adoption of ultra-high-definition content. Over 80% of new television models now support at least 4K resolution, creating substantial demand for compatible processing chips. As streaming platforms and broadcasters increasingly deliver content in 4K and emerging 8K formats, the need for advanced video bridge chips capable of handling higher bandwidth and complex format conversions becomes essential. Recent industry data indicates that 4K content now accounts for nearly 30% of all video streaming traffic worldwide, with projections showing this figure could exceed 50% within the next five years.

Commercial environments including digital signage, control rooms, and presentation systems are adopting multi-display configurations at an unprecedented rate. This trend is directly fueling the market for video interface chips that can manage multiple high-resolution outputs simultaneously. In retail applications alone, the deployment of video walls has grown by over 60% in the past three years, with each installation requiring sophisticated video processing solutions. The education sector’s rapid digital transformation, particularly in interactive learning environments, further contributes to this demand curve.

Modern vehicles now incorporate increasingly sophisticated entertainment and information systems, with premium models offering up to six high-resolution displays per vehicle. The automotive display market has grown at a compound annual rate exceeding 12% since 2020, driving corresponding demand for reliable video interface solutions. Next-generation automotive designs are eliminating traditional analog interfaces in favor of digital video transmission standards, requiring specialized chips that can operate reliably in challenging environmental conditions while meeting stringent automotive-grade certifications.

The rapid development of augmented and virtual reality technologies is opening significant opportunities for advanced video processing solutions. Next-generation headsets require ultra-low-latency video transmission with exceptionally high refresh rates – up to 120Hz for premium VR systems. This creates demand for specialized video interface chips that can maintain performance while minimizing power consumption. The AR/VR headset market is projected to grow at over 30% annually through 2030, representing a substantial new revenue stream for video chip manufacturers.

Artificial intelligence is transforming video processing through features like real-time upscaling, noise reduction, and content-aware encoding. This evolution creates opportunities for video chip designers to integrate dedicated AI acceleration capabilities directly into their products. Early implementations in flagship television models demonstrate the market potential, with AI-enhanced video processing commanding premium pricing. As these technologies mature, they’re expected to trickle down to mainstream devices, significantly expanding the addressable market for advanced video processing solutions.

The market is highly fragmented, with a mix of global and regional players competing for market share. To Learn More About the Global Trends Impacting the Future of Top 10 Companies https://semiconductorinsight.com/download-sample-report/?product_id=48075

Key Questions Answered by the HD Video Chip Market Report:

What is the current market size of Global HD Video Chip Market?

Which key companies operate in Global HD Video Chip Market?

What are the key growth drivers?

Which region dominates the market?

What are the emerging trends?

Browse More Reports:

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[+91 8087992013]

[email protected]

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leiditechelectonicpublishing · 13 days ago

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Guide to ESD Protection for Robot Vision CMOS Sensors

CMOS Sensors: A Precise Dance of Light and Electricity

With its three major advantages of low power consumption, high integration, and low cost, CMOS sensors have gradually replaced CCD sensors and are now widely used in fields such as smartphone photography, security monitoring, medical imaging, automotive electronics, industrial inspection, aerospace and military industries.

The main intrusion paths of electrostatic surges in industrial vision cameras with conventional CMOS sensor applications are power supplies, high — speed data interfaces, and trigger signal lines.

Leiditech Electronics recommends the following protection schemes for the key interfaces:

l Input power protection:

l CMOS high — speed data interface MIPI CSI — 2

*U1, U2 PIN 1–10, 2–9, 4–7, 5–6 are not connected internally in the chip and need to be connected by external wiring)

l Electrostatic protection for CMOS sensor power supply

Leiditech Electronics is committed to becoming a leading brand in electromagnetic compatibility (EMC) solutions and component supply. We offer a wide range of products, including ESD, TVS, TSS, GDT, MOV, MOSFET, Zener diodes, and inductors. With an experienced R&D team, we provide personalized customization services to deliver the highest quality EMC solutions tailored to our customers’ needs.

If you’d like to learn more or have any questions, don’t hesitate to reach out:

[[email protected]]

Visit us at [en.leiditech.com]

#CMOSSensor #RobotVision #ESDProtection #IndustrialAutomation #SmartFactory #ElectronicsDesign #EMC #TVSdiodes #SurgeProtection #Leiditech #TechInnovation #IoTProtection #MachineVision #HighSpeedData #IndustrialElectronics

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bananapi · 1 month ago

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Banana Pi BPI-F3 is a industrial grade RISC-V development board, with SpacemiT K1 8 core RISC-V chip, CPU integrates 2.0 TOPs AI computing power. 2/4/8/16G DDR and 8/16/32/128G eMMC onboard.2x GbE Ethernet prot,4x USB 3.0 and PCIe for M.2 interface, HDMI and Dual MIPI-CSI Camera.

#design

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cubeeye · 2 months ago

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Discover the Power of a Highly Accurate Depth Camera in Revolutionizing 3D Imaging Technology Across Industries | Cube-eye

Cube-eye is transforming 3D imaging technology with its I200 ToF 3D highly accurate depth camera. This compact and high-performance solution is designed for use in robotics, augmented reality, autonomous systems, and industrial automation. With exceptional depth perception, adaptability, and reliable performance, the I200 depth sensor is well-suited for many professional applications.

Precision & Accuracy in Depth Sensing

The I200 3d ToF depth sensor delivers high-resolution depth maps at 640 x 480 pixels and operates effectively within a range of 0.25 to 7 meters. It is equipped with a 940nm VCSEL illuminator and an advanced processing chip, which ensures depth accuracy within ±1% based on distance. This depth sensor is highly suitable for both indoor and outdoor environments, including bright sunlight conditions.

Smooth Output & Wide Field of View

With a 90° horizontal and 68° vertical field of view, the I200 captures a broad and detailed depth field. It operates at 15 frames per second, ensuring real-time and smooth data transmission, which is essential for applications such as autonomous vehicles, augmented reality interactions, and industrial automation.

Compact, Energy-Efficient, & Reliable

The I200 ToF 3D camera features a compact size of 52mm by 25.3mm by 35.5mm and weighs only 41.5 grams in the USB version.

It is highly power-efficient, operating on a 5VDC input with an average power consumption of just 2.5 watts.

It is designed to perform reliably in tough conditions, withstanding temperatures ranging from -5°C to 55°C.

Easy Integration & Broad Compatibility

It supports MIPI CSI-2 and USB interfaces for flexible hardware setups.

It works on Windows, Linux, and Android and supports ROS1/ROS2.

The developers can access Cube-eye’s SDK, APIs for C++ and Python, and USB drivers for easy software integration.

Applications Across Industries

The Cube-eye I200 depth sensor camera is ideal for robotics, enabling real-time navigation, obstacle detection, and enhanced spatial awareness.

It supports augmented reality applications by accurately mapping physical environments for improved interaction.

The camera enhances autonomous navigation by providing reliable depth perception for vehicles and drones.

In Industrial automation, the 3d depth data aids in object detection, precise measurement, and quality control processes.

For smart surveillance, it tracks movement and depth to improve monitoring and situational awareness.

If you are looking for a 3d depth data sensor, you can find them at Cube-eye.

Click here if you are interested in Cube-eye Cameras.

View More: Discover the Power of a Highly Accurate Depth Camera in Revolutionizing 3D Imaging Technology Across Industries

meerecompany will participate in IT exhibitions held in Korea and Singapore this May.

If you have even the slightest interest in machine vision technology, don’t miss the opportunity to experience meerecompany’s solutions at the following exhibitions!

[OktoberTech 2025]

Date: Thursday, May 22, 2025

Venue: COEX Convention Center 3F, Samseong-dong, Gangnam-gu, Seoul, Republic of Korea

Exhibition Info: https://www.infineon.com/cms/en/product/promopages/oktobertech/

[ATxSG 2025 – CommunicAsia 2025]

Date: Tuesday, May 27 – Thursday, May 29, 2025

Venue: Singapore Expo, Expo Drive, Singapore 486150

Booth: 4C3-4

Exhibition Info: https://asiatechxsg.com/

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siliconsignalsblog · 2 months ago

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Top GUI Frameworks and Display Protocols for Embedded Product Development in 2025

In today’s embedded systems, GUIs aren’t just screens — they’re the core of user interaction. Whether you're developing a wearable, an industrial controller, or a smart appliance, creating a seamless graphical user interface (GUI) is critical. This blog explores how to select the right type of LCD touch display, communication protocols, and GUI design tools that align with your product needs.

As a leading board bring-up company, Silicon Signals provides end-to-end board bringup services, with specialization in GUI porting and development using platforms like Qt, LVGL, EmWin, and GTK. Let’s dive into the key components to consider.

Types of LCD Touch Displays

Capacitive Touch Screens

Projected capacitive displays are widely used in consumer electronics like smartphones and tablets. They offer a smooth, responsive multi-touch experience, supporting gestures like pinch-to-zoom and swipe. These displays detect the conductivity of your fingers and perform exceptionally well in dry, clean environments.

Key Benefits:

Multi-touch support

High durability and sleek design

Fast response time

Limitations:

Not ideal for environments where gloves or non-conductive materials are used

Resistive Touch Screens

Resistive displays consist of two layers (plastic and glass) separated by a gap. When pressure is applied, the layers touch, registering the input.

Ideal for: Industrial and rugged environments where gloves or styluses are often used.

Advantages:

Can be operated with any object

Lower cost

Reliable in harsh environments

Drawback:

Requires more pressure, offers less responsiveness than capacitive touch

Display Communication Protocols

Choosing the right communication interface between your display and the processor is crucial for performance and system optimization.

SPI (Serial Peripheral Interface)

SPI is a widely-used protocol in embedded systems, especially when working with lower-resolution screens. It’s simple to implement and works well with basic touch GUIs.

Best suited for: Small displays (~480x360 resolution)

Benefits: Low resource requirements, easy integration on MCUs

Limitation: Not ideal for high-speed or high-res displays

DSI (Digital Serial Interface)

Developed by the MIPI Alliance, DSI is ideal for high-resolution and high-refresh-rate displays with fewer I/O pins required.

Best suited for: Mid-to-high-end embedded systems

Benefits: Power-efficient, scalable, and compatible with modern display controllers

Limitation: Licensing fees due to proprietary technology

HDMI

Used primarily in embedded Linux or high-performance products, HDMI offers the highest quality in terms of audio-visual integration.

Best suited for: Advanced GUIs in medical, aerospace, or industrial systems

Benefits: Combines audio and video, HDCP for secure content, supports large resolutions

Limitation: Requires a more powerful processor and consumes more power

GUI Development Tools & Libraries

Once you've selected your hardware, it’s time to choose a software tool that helps you design and port the GUI effectively. As a board bringup service provider, we at Silicon Signals have deep expertise in GUI porting using Qt, LVGL, EmWin, GTK, and Crank Storyboard.

1. Qt Framework

Qt is a professional-grade development platform used extensively in automotive, medical, and industrial applications.

Language: C++ and QML

Features: Cross-platform, hardware acceleration, built-in protocol support (HTTP, FTP, etc.)

Ideal for: Performance-sensitive, scalable GUIs

Note: Commercial license required for product deployment

We offer advanced Qt porting services for embedded Linux, Yocto-based boards, and RTOS platforms.

2. Crank Storyboard

Storyboard simplifies GUI development with drag-and-drop features, Photoshop imports, and support for animations and 3D elements.

Benefits: Designer-friendly, OS and platform agnostic, embedded engine optimization

Best for: Teams with both design and embedded development backgrounds

Limitation: Requires a license for commercial products

3. LVGL (Light and Versatile Graphics Library)

LVGL is ideal for resource-constrained microcontrollers, with footprint requirements as low as 64kB flash and 8kB RAM.

Languages: C and MicroPython

Platforms: STM32, ESP32, Raspberry Pi, PIC, etc.

GUI Builder: Beta version available

Strengths: Free, open-source, portable

Limitations: Limited for complex UIs or animations

Our team excels in integrating LVGL on custom MCUs and porting it for FreeRTOS and bare-metal systems.

4. EmWin by SEGGER

EmWin is a highly efficient, commercial-grade GUI library optimized for MCUs.

Developed by: SEGGER Microcontroller

Best for: Medical and industrial applications where reliability is non-negotiable

Strength: Real-time performance, minimal resource usage, certified for safety-critical applications

Limitation: Licensing and complexity

We provide EmWin integration services for NXP, STM32, and Renesas-based boards.

5. GTK (GIMP Toolkit)

GTK is a popular GUI library often used in Linux systems and is open-source.

Language: C (bindings available for Python, C++, etc.)

Best for: Embedded Linux systems where scalability and flexibility matter

Drawback: Not suitable for MCUs with limited RAM and Flash

Our engineers can port GTK-based UIs on embedded Linux devices, optimizing for performance and footprint.

Why Silicon Signals?

As a leading board bring-up company, Silicon Signals provides a one-stop solution for embedded product development. From hardware validation and board bringup services to GUI design and porting on popular frameworks like Qt, LVGL, TouchGFX, GTK, and EmWin — we ensure your product is market-ready with a seamless user experience.

Whether you need to develop a medical device UI, a rugged industrial HMI, or a sleek consumer interface, our engineers can help you choose the right display, protocol, and GUI framework.

Ready to design a powerful GUI for your embedded product? Reach out to our engineering team at [email protected] for a free consultation.

#embeddedtechnology #embeddedsoftware #embeddedsystems #linux kernel #androidbsp #linuxdebugging #android #aosp #iot development services #iotsolutions #embeddedgui #guidevelopment #guitools

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t2mip · 2 months ago

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USB 3.2 Gen1, Gen2 PHY Controller IP Cores

T2M-IP, a global specialist in semiconductor IP solutions, highlights its USB 3.2 Gen1 and Gen2 IP Core, a complete, production-proven PHY and Controller solution supporting 5Gbps and 10Gbps data transfer. Designed for performance, flexibility, and low power, this IP cores supports multi-lane operation and is optimized for a wide range of high-speed interface applications across consumer, automotive, and industrial domains.

Fully compliant with the USB 3.2 specification, the IP cores support Host, Device, OTG, Dual-Role, and Hub configurations. It is also USB Type-C compatible, enabling seamless integration into USB-C-based designs, including support for dual-role functionality and alternate mode readiness.

With the increasing adoption of USB Type-C and higher bandwidth peripherals, SoC designers are under pressure to deliver robust USB performance while minimizing power and area. T2M-IP’s USB 3.2 IP stands out by offering a unified, scalable solution that supports diverse use cases—from compact wearables and smartphones to high-throughput automotive infotainment and industrial control systems. Its adaptability across roles and applications makes it an ideal choice for future-proof designs.

Key Features of T2M-IP's USB 3.2 IP cores include:

High-Speed USB 3.2 Support: Compliant with Gen1 (5Gbps) and Gen2 (10Gbps), with support for multi-lane operation to boost throughput.

Flexible USB Roles: Highly configurable for Host, Device, OTG, Hub, and Dual-Role applications.

Type-C Integration Ready: Supports key USB Type-C features, ideal for modern SoCs with reversible connectors and dynamic role-switching.

Low Power & Compact Footprint: Optimized PHY architecture ensures minimal area and power, perfect for mobile and embedded systems.

Robust Signal Performance: Built-in signal integrity and error-handling features ensure reliable performance in harsh environments.

Proven Across Markets: Successfully deployed in automotive, external storage, consumer electronics, gateways, and industrial systems.

T2M-IP’s USB 3.2 Gen1/Gen2 solution is part of a rich interface IP cores portfolio that includes PCIe, HDMI, DisplayPort, MIPI, DDR, Ethernet, V-by-One, SD/eMMC, and programmable SerDes, all available with matching PHYs. IP cores are silicon-proven and available across leading foundries and advanced process nodes.

Immediate licensing Availability: These Semiconductor Interface IP Cores are immediately available for licensing as stand-alone IP Cores or with pre-integrated Controllers and PHYs. Please submit a request / MailTo for more information on licensing options and pricing.About T2M: T2M-IP is a global independent semiconductor technology expert, supplying complex semiconductor IP Cores, Software, KGD, and disruptive technologies to allow faster development of your Wearables, IOT, Automotives, Communications, Storage, Servers, Networking, TV, STB, and Satellite SoCs. For more information, please visit www.t-2-m.com

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adafruit · 2 years ago

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ICN6211 DSI demo with 5" 800x480 display on a Raspberry Pi 🔌📟👨‍💻

To test out the icn6211 library and circuit configuration, we've connected up a 5" diagonal 40-pin 800x480 display . It was pretty sweet when the desktop image appeared! one of the nice things about using the MIPI/DSI interface is all the GPIO and HDMI ports remain unused, and the ICN is waaay cheaper than an HDMI-to-TFT converter chip. We have another rev we're going to spin that makes I2C configuration a little easier

#adafruit #raspberrypi #electronics #pcb #opensource #opensourcehardware #icn6211 #dsidemo #circuitpython #gpio #hdmi #tftconverter #hardwarerevamp #i2cconfiguration #electronicsengineer #manufacturing #nyc #technology

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digitalmore · 2 months ago

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#IFTTT #Digital More

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sincerefirst-aiotmodule · 20 days ago

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5MP OV5640 MIPI Camera Module

The OV5640 MIPI camera module is based on a 5-megapixel sensor, supports MIPI-CSI and DVP interfaces, has a 3mm focal length, F2.2 aperture, and D76.6° viewing angle. It is widely used in smart homes, vehicle systems, face recognition, robots, medical testing, AR/VR and other fields. It has a compact size, excellent performance, and is compatible with a variety of embedded platforms.

GUANGZHOU SINCERE INFORMATION TECHNOLOGY LTD. Attn.: Ms. Annie Skype/E-mail: [email protected] M.B/Whatsapp:+8617665309551 Sincere Eco-Industrial Park, GuanNanYong Industrial Zone, GZ

#youtube #camera module

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forlinx · 2 months ago

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Compact. Robust. Intelligent. Discover the Forlinx i.MX9352 SoM

The Forlinx FET-MX9352-C SoM powered by NXP's i.MX 9352 processor delivers industry-leading multi-core performance, ultra-efficient AI inference, and deterministic networking in a compact, SMT-friendly form factor, making it ideal for industrial automation, robotics, edge AI, and smart IoT applications.

Key Performance Highlights

High-Performance Processing

Dual Cortex-A55 @ 1.7 GHz handles complex Linux workloads and multi-threaded applications with ease.

Cortex-M33 @ 250 MHz real-time core delivers deterministic control and low-latency tasks without offloading to external MCUs.

Edge AI Acceleration

Arm Ethos-U65 microNPU achieves up to 0.5 TOPS of AI acceleration for vision and machine-learning inference at the edge.

On-board NPU enables secure, offline inferencing for applications like predictive maintenance and intelligent video analytics.

Deterministic Networking

Dual Gigabit Ethernet ports—one with TSN (Time-Sensitive Networking) support—ensure sub-millisecond synchronization and zero-packet loss for real-time industrial networks.

Built-in IEEE 1588 & 802.1Qbv/bu standards support precise time synchronization across distributed systems.

Rich Connectivity

Comprehensive interfaces include 2× USB 2.0, 2× CAN-FD, 3× SD/SDIO 3.0, up to 8× UART, 8× SPI, 8× I²C, 2× I³C, and audio interfaces (SPDIF, PDM).

High-speed multimedia features with 1× 4-lane MIPI-DSI, 1× LVDS, RGB888 output, and up to 2-lane MIPI-CSI for camera input.

Industrial Reliability & Longevity

Wide-temperature operation from –40 °C to +85 °C with all industrial-grade components for harsh environments.

15-year longevity program aligns with NXP's supply guarantee for the i.MX 93 family, ensuring stable supply through at least 2038.

Compact SMT-Ready Design

QFN SMT module measures just ~33 × 48 mm and can be directly reflow-soldered onto customer carrier boards, reducing BOM cost and assembly complexity.

Optimized signal integrity & power management deliver robust performance in a miniaturized footprint.

Elevate your next project with the FET-MX9352-C SoM's unmatched compute, AI, and network determinism.

🔗 Explore product details & request samples

#iMX93SoM #SystemOnModule #EmbeddedSystems #IndustrialIoT #EdgeAI #CortexA55 #EthosU65 #TimeSensitiveNetworking

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