Multi-Display HAT First-Ever Raspberry Pi HAT to Feature Five Onboard Color TFT Displays

 MozTech has just launched their latest creation — the Multi-Display HAT for Raspberry Pi — a compact yet powerful HAT that integrates five mini TFT displays into one sleek board. Whether you're building advanced dashboards, interactive control panels, or just want your Raspberry Pi setup to look awesome, this is a game-changer.

The Multi-Display HAT is now available on Kickstarter for just $39, with special early-bird pricing for the fastest backers!

The Multi-Display HAT is an expansion board for Raspberry Pi that combines five onboard high-quality TFT displays of various sizes, driven by both an onboard RP2040 co-microcontroller and the Raspberry Pi itself. It enables you to visualize more data and controls in a smaller footprint — no need for multiple external screens!

Displays included:

• 1x 1.14” TFT Display
• 1x 0.85” TFT Display
• 2x 0.96” TFT Displays
• 1x 1.3” TFT Display (capable of running Raspberry Pi OS!)

The RP2040 handles four displays, while the 1.3” display is driven directly by the Raspberry Pi — and yes, you can run Raspberry Pi OS on that 1.3” screen!

Imagine a single HAT that shows real-time CPU stats, temperature, memory usage, sensor readings, and even a full Linux desktop — all at once. That’s exactly what the Multi-Display HAT delivers.

Tiny OS Screen

The 1.3” display can run the entire Raspberry Pi OS. It may be tiny, but it’s fully functional — ideal for ultra-compact Raspberry Pi setups, wearable interfaces, or DIY embedded terminals. It brings full GUI functionality to a screen small enough to fit in your palm.

“A full desktop experience on a 1.3” display – it’s small, but it works!”

Aside from its utility, the Multi-Display HAT looks stunning. Whether you’re displaying a single image across all five displays, visualizing data in parallel, or creating interactive controls, this HAT turns your Raspberry Pi into an interactive art piece.

“A single image — spread beautifully across 5 TFT displays.”

You can even change the orientation of each display for flexible layouts — portrait, landscape, or a mix of both!

The Multi-Display HAT for Raspberry Pi is a standout tool that opens up new display possibilities on a compact platform. Whether you're building dashboards, terminals, smart interfaces, or just love experimenting with screen-rich projects, this HAT gives you power, flexibility, and stunning visual design. Back the Multi-Display HAT onKickstarter today – Starting at just $39!

Recalbox RGB DUAL 2 - The Ultimate CRT Gaming Experience for Raspberry Pi 5

 The world of retro gaming just received a major upgrade with the launch of the Recalbox RGB DUAL 2! Designed exclusively for the Raspberry Pi 5, this device promises to revolutionize CRT gaming, offering pixel-perfect visuals, enhanced audio, and broad compatibility with retro consoles. If you’re a fan of nostalgic gaming experiences, then this is the hardware you've been waiting for!

Recalbox has been a major player in the retro gaming community, constantly pushing the boundaries of what’s possible with single-board computers like the Raspberry Pi. With the release of the Raspberry Pi 5, the need for a dedicated solution to bring classic gaming experiences to CRT screens became evident. Recalbox RGB DUAL 2 fills this gap by providing a fully amplified 15kHz and 31kHz RGB video signal, composite video output, and high-fidelity I2S DAC audio.

Key Features:

Next-Level Video Output

• Native Raspberry Pi 5 support with optimized audio management.
• Amplified RGB video signal for pixel-perfect 15kHz and 31kHz output.
• Composite video support for broader CRT TV compatibility.
• Dynamic resolution switching to mimic original hardware behavior.
• New 240p@120Hz VGA mode for sharper visuals on PC monitors.
• Native support for GunCon 2 for light gun games (experimental feature).
• Automatic HDMI switching for modern displays.

Expanded Audio Capabilities

• High-resolution I2S DAC audio (up to 384kHz/32-bit sampling).
• Multiple audio outputs:
• SCART: Integrated for TV speakers.
• 3.5mm jack: For headphones, RCA adapters, or external amplifiers.

Broad Compatibility & Connectivity

• Supports 4:3 and 16:9 aspect ratios.
• Works with SCART, RCA, VGA, and 3.5mm audio/composite jack.
• Automatic resolution switching to preserve original gaming experience.
• Works with retro consoles and arcade setups for an authentic experience.

A Game-Changer for Retrogaming on Raspberry Pi 5

The Raspberry Pi 5 significantly improves on its predecessor, allowing faster start-ups, smoother navigation, and compatibility with more games. The Recalbox RGB DUAL 2 takes full advantage of this power boost, enabling:

• Cave arcade games to run at 60FPS.
• GameCube emulation (currently under development).
• 3D arcade games from MAME (ZN1, ZN2, System 10/11/12, etc.).
• Better fluidity in 480p games.

The RecalTower: A Modular Gaming Setup

To complement the RGB DUAL 2, Recalbox has also introduced the RecalTower, a stackable case for Raspberry Pi 5 that neatly integrates with the RGB DUAL 2 module. Designed for future expansions, the RecalTower allows users to stack additional features over time.

The Recalbox RGB DUAL 2 is currently available for pre-order on Kickstarter, along with exclusive perks and add-ons:

• Limited Patron Edition (Black) for Recalbox Patreon supporters.
• RecalTower case for modular expansions.
• Exclusive PCB collectible pack with keychains and coasters.

The Recalbox RGB DUAL 2 is shaping up to be the ultimate solution for retro gaming on CRT displays. Whether you’re looking to relive your childhood gaming experiences or explore the capabilities of the Raspberry Pi 5, this hardware offers a seamless and authentic retro gaming experience.

Raspberry Pi Just Announced - Raspberry Pi PoE+ Injector at $25 Available on The PiHut

 Raspberry Pi continues to expand its ecosystem with innovative and practical accessories, and their latest addition—the RaspberryPi PoE+ Injector—simplifies power delivery for networked Raspberry Pi projects. Whether you're running a Raspberry Pi in an industrial setting or a home automation project in a remote location, this new injector allows you to provide power and data over a single Ethernet cable.

The Raspberry Pi PoE+ Injector is a compact midspan injector designed to add Power-over-Ethernet (PoE) support to your network. If you don't have a PoE-enabled switch, this device acts as an intermediary, injecting power into the Ethernet cable while maintaining seamless data transmission.

With a price tag of just $25, it’s an affordable and effective solution for powering Raspberry Pi single-board computers (SBCs) and other PoE-enabled devices.

Raspberry Pi PoE+ Injector Specifications:

Power & Connectivity

• Standards Support – IEEE 802.3af (PoE, 13W) and IEEE 802.3at (PoE+, 25W)
• Input Voltage – 100V - 240V AC
• Output Voltage – 48V DC

PoE Functionality

• Type – Midspan Injector
• Network Speed – 10/100/1000 Mbps (Gigabit Ethernet)
• Connector Type – RJ45 Ethernet (Input & Output)

Compatibility

• Works with – Raspberry Pi SBCs (when used with a PoE/PoE+ HAT)
• Supports Other Devices – Compatible with other IEEE 802.3af/at PoE-powered devices

Physical Dimensions & Build

• Compact Form Factor – Easy to integrate into any setup
• Mounting – Desktop or wall-mountable

Additional Notes

• Developed in collaboration with – Microchip
• Required Accessory – IEC mains lead (sold separately)

 For many Raspberry Pi enthusiasts, projects often take them beyond the reach of convenient power outlets. Whether it’s a remote garden webcam, IoT sensor, or an industrial controller, running a separate power cable can be inconvenient or impossible. PoE technology solves this by delivering both power and data over a single Ethernet cable, making it an ideal solution for:

• Remote and outdoor installations
• Security cameras
• Industrial automation
• IoT applications

Since the Raspberry Pi 3B+, all Raspberry Pi SBCs have supported PoE when paired with an optional PoE or PoE+ HAT. However, without a PoE switch, powering these devices required additional adapters—until now.

The Raspberry Pi PoE+ Injector was developed in collaboration with Microchip and includes the following features:

• Standards Support: IEEE 802.3af (PoE, 13W) and IEEE 802.3at (PoE+, 25W)
• Input Voltage: 100V - 240V AC
• Compatible with Raspberry Pi SBCs (when used with a PoE/PoE+ HAT)
• Compact and easy to install
• Ideal for networked Raspberry Pi projects and other PoE-powered devices

While the Raspberry Pi 5 includes a 4-pin PoE power connector, the first-party PoE+ HAT+ is still under development. Raspberry Pi hints that this will be their most efficient Powered Device (PD) accessory yet, and it has been in the works for quite some time. Until it officially launches, users can still take advantage of PoE with existing Raspberry Pi models using the new injector.

For Raspberry Pi users who want a cost-effective and hassle-free PoE solution, the Raspberry Pi PoE+ Injector is a must-have and currently available on The PiHut. It ensures that even if you don't have a PoE switch, you can still power your Raspberry Pi and other PoE devices with ease.

What do you think about this latest addition to the Raspberry Pi ecosystem? Will you be incorporating it into your projects? Let me know in the comments below!

HackCable - The Ultimate USB-C Keystroke Injection Tool for Ethical Hackers and Cybersecurity Pros

 Kickstarter recently featured HackCable, a USB-C cable designed for cybersecurity research and system testing. While it may look like an ordinary charging cable, HackCable packs powerful features like built-in Wi-Fi and keystroke injection, making it a discreet yet versatile tool for cybersecurity professionals and researchers alike.

HackCable Versions: ESP32-S3 or RP2040

HackCable is available in two versions, each powered by a different microcontroller: the ESP32-S3 and the RP2040. Both versions provide unique capabilities for various use cases, from advanced wireless operations to simple offline tasks.

1. Wi-Fi Version: Powered by ESP32-S3

The Wi-Fi-enabled version of HackCable features the ESP32-S3 microcontroller, designed for users who need advanced functionality and remote operation capabilities. This version is equipped with:

• Built-in Wi-Fi Hotspot: The ESP32-S3 enables remote operations via a built-in Wi-Fi hotspot, allowing users to control the cable from a smartphone or other devices.
• Dual-Core Processor: The ESP32-S3 offers a dual-core processor running at speeds of up to 240 MHz, making it perfect for complex tasks and high-performance applications.
• Integrated Wi-Fi and Bluetooth: The microcontroller supports 2.4 GHz Wi-Fi and Bluetooth 5, ensuring reliable and long-range connectivity for remote control and communication.
• Master-Slave Configuration: Multiple HackCables can be synchronized for coordinated operations, expanding the tool's potential for more complex tasks.

This version is ideal for ethical hackers, penetration testers, and cybersecurity professionals who need flexibility, wireless control, and the ability to operate from a distance.

2. Standard Version: Powered by RP2040

The standard version of HackCable is built around the RP2040 microcontroller, offering a more cost-effective solution for those who don’t require wireless control but still need powerful keystroke injection capabilities. Key features include:

• Dual-Core ARM Cortex-M0+ Processor: Running at up to 133 MHz, the RP2040 provides solid performance for executing keystroke injection tasks.
• 2MB Onboard QSPI Flash: Ample memory for storing scripts and configurations.
• USB 1.1 Support: Full-speed USB support enables seamless integration with various devices.
• Programmable GPIO Pins: With 26 programmable GPIO pins, the RP2040 offers flexibility for hardware customizations and additional functionalities.

The RP2040-powered version is perfect for beginner hackers, hobbyists, or researchers who need a reliable, offline tool for testing and automation.

Compatibility and Integration

HackCable is compatible with multiple operating systems, including Windows, macOS, Linux, Android, and iOS. Its plug-and-play functionality ensures quick setup and seamless integration, letting you focus on your work instead of configuration issues.

Open Source and Programmability

HackCable is open source, allowing developers to modify the firmware and tailor the device to specific needs. Whether you're programming in Python, C/C++, MicroPython, or other languages, HackCable offers the flexibility to customize its features. With extensive developer support, you can easily write scripts, automate tasks, or expand functionality for your specific use case.

Pricing and Availability

HackCable is available for early backers at discounted prices:

• RP2040 Version: $45
• Wi-Fi Version (ESP32-S3): $55

These prices are available for a limited time, so be sure to check out the Kickstarter page for more details on additional options and features.

Whether you're a cybersecurity researcher, ethical hacker, or just a tech enthusiast, HackCable provides an innovative and powerful tool for system testing and vulnerability assessments. With its discreet design, versatile functionality, and ease of use, HackCable is set to become an essential part of your cybersecurity toolkit. Don't miss out on this game-changing device—get yours today at an early backer price!

Long Range MESH Decentralized IoT Network Based on LoRa® | Reach 65,535 Nodes & Up to 62.5 Kbps data Transfer Speed

 Recently launched the Long Range MESH Decentralized IoT Network Based on LoRa® on Kickstarter: . This cutting-edge device supports an impressive 65,535 nodes, provides a 2.5 km communication range, enables remote configuration, features automatic routing, boasts network self-healing, offers data transfer speeds of up to 62.5 Kbps, and is globally compatible.

Two Powerful Variants to Choose From:

1. LoRa MESH HAT for Raspberry Pi

2. LoRa MESH USB Dongle

Both variants are built on the latest LoRa MESH technology, operating in the 410-509 MHz and 850-929 MHz frequency bands, with default settings of 433 MHz and 868 MHz, respectively. These devices provide robust and reliable communication for diverse IoT applications.

Key Features of the LoRa MESH Devices:

• Decentralized Network: Eliminates the need for a central coordinator, allowing for seamless and scalable networking across thousands of nodes.
• Self-Healing Capabilities: The network autonomously identifies and reroutes around failed communication links, ensuring consistent and uninterrupted data flow.
• Multi-Level Routing: Automatically creates efficient data paths for large-scale networks of up to 65,535 nodes.
• Advanced CSMA Mechanism: Utilizes Carrier Sense Multiple Access (CSMA) to minimize signal collisions, ensuring stable communication even in busy environments.
• Flexible Communication Modes: Supports Unicast, Multicast, Broadcast, and Anycast, making it adaptable to various applications and scenarios.

This powerful wireless MESH networking module leverages the latest LoRa spread spectrum technology. With a maximum output power of +22 dBm, an air data rate of 62.5 Kbps, and a baud rate of up to 460800 bps, the devices are designed for efficient and reliable data transmission. They operate in a frequency range of 410.125 - 509.125 MHz (default 433.125 MHz) and 850.125 - 929.125 MHz (default 868.125 MHz).

Specifications:

SoC & Networking

• LoRa MESH Module: Utilizes the latest LoRa® MESH technology for decentralized IoT networking.
• Frequency Range:
• 410.125 - 509.125 MHz (Default 433.125 MHz)
• 850.125 - 929.125 MHz (Default 868.125 MHz)
• Channel Support:
• 100 channels with 1 MHz spacing in the 410-509 MHz band.
• 80 channels with 1 MHz spacing in the 850-929 MHz band.
• Maximum Output Power: +22 dBm
• Air Data Rate: Up to 62.5 Kbps
• Serial Baud Rate: Up to 460,800 bps
• Communication Range: Up to 2.5 km (line of sight)
• Node Capacity: Supports up to 65,535 nodes in a single network.

Device Variants

1. LoRa MESH HAT for Raspberry Pi
• Compatibility: Fits any Raspberry Pi with a 40-pin GPIO header.
2. LoRa MESH USB Dongle
• Compatibility: USB connectivity for Raspberry Pi, Banana Pi, Google Coral Dev Board, Jetson Nano, Orange Pi, Windows, and macOS.
• Form Factor: Compact and portable, plug-and-play via USB.

Routing & Networking

• Decentralized Network Structure: No central coordinator required; utilizes routing and terminal nodes.
• Self-Healing: Automatically re-routes around failed links.
• Multi-Level Routing: Efficient routing paths for up to 65,535 nodes.
• Advanced CSMA (Carrier Sense Multiple Access): Reduces signal collisions.

Communication & Data Transfer

• Modulation Method: LoRa® modulation for long-range communication and interference resistance.
• Data Transfer Speed: Supports data rates up to 62.5 Kbps.
• Flexible Communication: Options for Unicast, Multicast, Broadcast, and Anycast.
• Security: Built-in encryption for data privacy and verification checks for accuracy.

Power & Electrical Specifications

• Power Supply: 5V from the Raspberry Pi GPIO header or USB power for the Dongle.
• Power Consumption: Low-power operation suitable for battery-powered applications.

Compatibility & Software

• Operating System Support: Windows, macOS, Raspberry Pi OS, Ubuntu, Linux.
• Development Environments: Supports Python, Arduino, and custom C/C++ applications.
• Firmware: Upgradable over-the-air (OTA) for future updates.

Physical Specifications

• Dimensions:
• LoRa MESH HAT: Standard Raspberry Pi HAT size.
• LoRa MESH USB Dongle: Compact USB stick form factor.
• Connector Types: 40-pin GPIO for HAT, USB-A for Dongle.
• Indicator LEDs: Status and communication activity indicators.

Environmental Specifications

• Operating Temperature: -20°C to 60°C
• Storage Temperature: -40°C to 85°C
• Humidity: 10% to 90% non-condensing

Our LoRa MESH modules provide advanced functionality to meet a wide range of applications, including smart homes, industrial monitoring, wireless security, building automation, smart agriculture, and more. Here are some of the standout features:

• Decentralized and Scalable: No central node is required, simplifying network setup and enhancing scalability.
• Self-Routing & Multi-Level Routing: The system automatically determines the most efficient paths for data delivery, ensuring reliable communication across large networks.
• Network Self-Healing: The MESH network dynamically finds alternative routes when communication links fail, maintaining stable connections.
• High Performance: Operates in globally supported frequency ranges, with flexible settings for optimized performance in different environments.

Frequency and Channel Details:

• 410.125 - 509.125 MHz: 100 channels, each spaced 1 MHz apart.
• 850.125 - 929.125 MHz: 80 channels, each spaced 1 MHz apart.

The LoRa MESH Device Variants:

LoRa MESH HAT for Raspberry Pi:

The LoRa MESH HAT is designed specifically for Raspberry Pi enthusiasts and professionals. It integrates seamlessly with any Raspberry Pi model featuring a 40-pin GPIO header, providing a powerful mesh networking solution. Ideal for complex IoT setups, smart homes, agriculture, and more, the HAT supports up to 65,535 nodes, enabling extensive and decentralized networks without relying on centralized infrastructure.

This variant includes advanced features like path optimization and self-healing to ensure consistent communication, even if certain nodes go offline. Additionally, its remote configuration capabilities allow for easy adjustments from anywhere, making it perfect for large-scale projects. The HAT supports a range of communication protocols, making it highly adaptable across different platforms.

LoRa MESH USB Dongle:

The LoRa MESH USB Dongle is a compact yet powerful solution, offering high-performance mesh networking in a portable format. Plug it directly into any computer, laptop, or compatible microcontroller with a USB port, and it’s ready to go. Despite its small size, the USB Dongle delivers the same advanced features as the HAT, including support for 65,535 nodes, automatic path optimization, and network self-healing.

Compatible with a wide range of single-board computers—like Raspberry Pi, Banana Pi, Google Coral Dev Board, Jetson Nano, and Orange Pi—the USB Dongle is highly versatile. It also works with Windows and Mac PCs, supporting various operating systems including Windows, macOS, Raspberry Pi OS, Ubuntu, and Linux. Furthermore, it is compatible with popular development environments like Python and Arduino, making it an excellent choice for diverse projects.

Key Benefits:

• LoRa MESH Networking: Utilizes advanced LoRa modulation for enhanced long-range communication and interference resistance.
• Massive Network Capacity: Handles up to 65,535 nodes, with a recommended practical network size of 200 nodes for optimal performance.
• Decentralized Structure: Streamlines network management using routing and terminal nodes, eliminating the need for a central coordinator.
• Self-Healing & Path Optimization: Continually refines routing paths, ensuring the most efficient communication routes and reliable data delivery.
• Versatile Communication: Four distinct modes—Unicast, Multicast, Broadcast, and Anycast—allow for flexible data transmission tailored to various needs.
• High Security & Reliability: Incorporates robust encryption for data security, along with multiple verification checks for data accuracy.
• Remote Configuration: Easily modify communication parameters for the entire network remotely, streamlining maintenance and updates.

The LoRa MESH devices are now available on Kickstarter with special early bird pricing starting at just $25 for the USB Dongle and $35 for the Raspberry Pi HAT. Don't miss the opportunity to back this innovative project and be part of the future of decentralized IoT networks. Check out the Kickstarter page to secure your device and explore all the possibilities that LoRa MESH can bring to your next project!

Vcc Labs has introduced the Nova - A Compact, Open-Source RP2040 Development Board with RGB LED Matrix

 Vcc Labs has introduced the Nova, a small yet powerful open-source hardware development board built around the Raspberry Pi RP2040. Featuring a USB-C port, a bright 70 RGB LED matrix arranged in a 7x10 grid, and two 12-pin GPIO headers, the Nova is designed to be versatile and expandable. It’s perfect for projects like wearables, compact displays, interactive art installations, and simple games.

Key Features of the Nova

• Microcontroller: Raspberry Pi RP2040 dual-core Cortex-M0+ running at up to 133 MHz with 264KB SRAM.
• Storage: Equipped with 2MB QSPI flash.
• LED Display: A matrix of 70 WS2812 RGB LEDs, each LED measuring a tiny 1x1 mm, providing vibrant color and high customizability.
• USB Connectivity: USB Type-C port for power, data transfer, and programming.
• Expansion Options: Two 12-pin headers give access to 20 GPIOs, dual SPI, I2C, UART interfaces, 4x ADC, and pins for Vin, 5V, 3.3V, and GND.
• Additional Features: Comes with a reset button and BOOT button for easy firmware management.

Power and Dimensions

• Power Sources:
• 5V through the USB-C port.
• 7V to 18V through the Vin pin.
• Power Usage: Consumes up to 9 watts when all LEDs are set to full brightness.
• Size and Weight:
• Dimensions: 30.48 x 20.32 mm (without case).
• Weight: 4.76 grams with headers, 3 grams without headers.
• Operating Temperature: Can function in temperatures ranging from -20°C to +85°C.

Programming the Nova

The Nova is compatible with a variety of programming environments:

• Official Raspberry Pi SDK: Use C/C++ for low-level programming.
• MicroPython: Perfect for quick development and scripting.
• Arduino IDE: Utilize familiar Arduino libraries for project creation.

Code samples are available on GitHub, including five classic games: Ball Brick, Flappy Bird, Snake, Space Invaders, and Tetris. These games can be played by connecting five buttons to GPIO pins 2-6. Although the hardware directory currently includes only the Bill of Materials (BoM) and board dimensions, Vcc Labs plans to release full schematics and design files as the Nova is an open-source project. These resources are expected to become available once the crowdfunding campaign concludes.

Nova in Context

The Nova isn't the first RGB LED matrix development board on the market. Other examples, like the 01Space ESP32-based 25 RGB LED matrix boards and Waveshare's ESP32-S3-Matrix board with 64 RGB LEDs, offer similar functionality. However, the Nova stands out with its 70-LED matrix and its use of the RP2040 microcontroller, providing a balance of advanced features without built-in wireless connectivity.

Crowdfunding on Kickstarter

Vcc Labs has launched the Nova on Kickstarter with a modest funding goal of 3,000 Euros. A single Nova board starts at just 18 Euros (around $20 USD), with discounts available for bulk pledges of up to 10 boards. Shipping fees range widely from 3 to 48 Euros, depending on the delivery destination. If all goes as planned, backers should receive their boards by January 2025.

Whether you’re a hobbyist looking to create a unique wearable or an artist seeking to explore interactive lighting, the Nova offers a flexible and compact platform to bring your ideas to life.

 

Raspberry Pi CM5 and Compute Module IO Board: A First Look at the Next Big Thing in Embedded Computing

 Exciting news has just dropped from Electronica 2025, where the much-anticipated Raspberry Pi Compute Module 5 (CM5) and its companion Compute Module IO Board made an unexpected appearance. Although details remain limited, the leaked images have already created a buzz within the tech community. Here’s everything we know so far!

What We Know So Far

At Electronica 2025, we got our first glimpse of the Compute Module 5. This marks the next step in the evolution of Raspberry Pi's Compute Module series, and while official specs are still under wraps, we can gather some insights from the leaks and predictions.

Design

The CM5 looks strikingly similar to its predecessor, the Compute Module 4 (CM4), in terms of form factor. However, there are likely some subtle design tweaks and improvements that will enhance its overall functionality. The compact, board-level design remains a staple for embedded projects, but with a few key upgrades to meet the needs of modern tech.

Enhanced Performance

With the Raspberry Pi 5 recently launching and bringing improvements in processing power, it’s expected that the CM5 will follow suit. We anticipate a more powerful CPU, likely with better processing speeds, more memory options, and improved connectivity. Expect a more efficient design that can handle demanding applications, from IoT to industrial automation and beyond.

What About the Compute Module IO Board?

Accompanying the CM5 is the Compute Module IO Board, which is likely to offer the essential ports and interfaces that have made the Raspberry Pi family so popular. Expect to see:

• USB Ports for connecting peripherals
• HDMI Output for displays
• Ethernet Connectivity for reliable networking
• GPIO Pins to interface with Raspberry Pi HATs and custom applications

This combination of the CM5 and IO Board will make it easier for makers and engineers to build embedded systems that need both performance and flexibility.

When Will We See the Official Compute Module 5 Release?

Although Raspberry Pi has yet to announce an official release date for the CM5, the appearance at Electronica 2025 has certainly piqued our curiosity. With Raspberry Pi 5 already launched, the Compute Module 5 is expected to follow in the near future.

While the full release may still be a year or more away, 2026 seems like a reasonable speculation for when we could see the official launch. In the meantime, we expect more details to surface later this year, so stay tuned for updates!

What’s Next?

It’s clear that Raspberry Pi is gearing up to release some exciting new hardware, but we’ll need to wait for official confirmation on specifications, features, and pricing. As more information becomes available, we’ll be sure to update you on everything you need to know about the CM5 and Compute Module IO Board.

For now, we can only speculate, but one thing is for sure: the future of embedded computing is looking brighter than ever with these new advancements from Raspberry Pi.

Check Out the Leaked Image Below!

Here’s a first look at the Raspberry Pi CM5 and the Compute Module IO Board in all their glory. What do you think about the new design and the potential upgrades? Let us know your thoughts in the comments below!

Stay Connected

Don't forget to subscribe for more updates on the Raspberry Pi CM5, upcoming tech releases, and everything happening in the world of embedded computing!

What are your thoughts on the Compute Module 5? Are you excited for its release, or do you have any predictions about its specs and capabilities? Drop your thoughts in the comments—we’d love to hear from you!

Raspberry Pi Introduced The Public Beta of the Raspberry Pi Pico Visual Studio Code Extension

 Exciting news for Raspberry Pi enthusiasts! Raspberry Pi has officially launched the public beta of the Pico Visual Studio Code Extension, making it easier than ever to develop projects for the Pico-series boards.

What is Pico VS Code?

The Pico VS Code Extension is designed specifically for Microsoft Visual Studio Code users. Whether you’re a beginner or an experienced developer, this tool streamlines the process of creating, developing, and debugging your Raspberry Pi Pico projects.

Setting up an embedded development environment can often be a daunting task. Many beginners struggle with the complexities of build systems, SDKs, and toolchains, while even seasoned developers can find themselves bogged down by tedious setup processes. Cross-compilation—developing on one machine to run code on another—adds another layer of complexity that can be frustrating for everyone involved.

That’s where the Pico VS Code Extension comes in. Raspberry Pi has listened to community feedback and refined the extension to simplify the development process. With this tool, you can get started coding in an environment you already know and love—Visual Studio Code—without getting lost in the nitty-gritty details.

Why Choose the Pico VS Code Extension?

• User-Friendly: Designed to take the guesswork out of setting up your development environment, allowing you to focus on bringing your projects to life.
• Time-Saving: Eliminate the frustrating setup processes that can eat into your valuable development time.
• Supports All Skill Levels: Whether you’re blinking your first LED or tackling more complex projects, the Pico VS Code Extension is here to guide you every step of the way.

Getting Started

Ready to dive in? Here’s how you can get started with the Pico VS Code Extension:

1. How do I get Pico VS Code?
   Learn about the installation process and prerequisites.
2. Installing the Pico VS Code Extension
   Follow step-by-step instructions to install the extension in your Visual Studio Code.
3. Building a Blink Example with Pico VS Code
   Get hands-on by creating your first project—a simple blink example!
4. How to Update the Project Configuration
   Discover how to update your project settings to suit your needs.

For complete instructions on these topics, check out the official guide here.

Happy coding! With the Pico VS Code Extension, transforming your ideas into reality has never been easier.