This is an I/O expansion kit designed for Raspberry Pi, which provides 5 sets of 2x20 pinheaders, that means a handy way to 'stack' multi different HATs together, and use them as a specific combination / project.
Features
Standard Raspberry Pi connectivity, directly pluggable OR through ribbon cable
5 sets of 2x20 pinheaders, connect multi HATs together
USB external power port, provides enough power supply for multi HATs
Clear and descriptive pin labels for easy use
Reserved jumper pads on the bottom side, pin connections are changeable by soldering, to avoid pin conflicts
Note: make sure there are no any pin conflicts between the HATs you want to use together before connecting.
Specifications
Dimensions: 183 × 65 mm
Mounting hole size: 3 mm
Included
1x Stack HAT
1x Ribbon cable 40-Pin
1x 2x20 male pinheader
1x RPi screws pack (4pcs) x1
Specifications
CM4 socket
Suitable for all variants of Compute Module 4
Networking
Gigabit Ethernet RJ45 connectorM.2 M KEY, supports communication modules or NVME SSD
Connector
Raspberry Pi 40-PIN GPIO header
USB
2x USB 2.0 Type A2x USB 2.0 via FFC connector
Display
MIPI DSI display port (15-pin 1.0 mm FPC connector)
Camera
2x MIPI CSI-2 camera port (15-pin 1.0 mm FPC connector)
Video
2x HDMI port (including one port via FFC connector), supports 4K 30fps output
RTC
N/A
Storage
MicroSD card socket for Compute Module 4 Lite (without eMMC) variants
Fan header
No fan control, 5 V
Power input
5 V
Dimensions
85 x 56 mm
Included
1x CM4-IO-BASE-A
1x SSD mounting screw
Downloads
Wiki
The official Raspberry Pi mini-HDMI to HDMI (A/M) cable designed for all Raspberry Pi Zero models. 19-pin HDMI Type D(M) to 19-pin HDMI Type A(M) 1 m cable (white) Nickel-plated plugs 4Kp60 compliant RoHS compliant 3 Mohm 300 VDC insulation, withstands 300 VDC for 0.1s
A Fast-Lane Ride From Concept to Project
The core of the book explains the use of the Raspberry Pi Zero 2 W running the Python programming language, always in simple terms and backed by many tested and working example projects. On part of the reader, familiarity with the Python programming language and some experience with one of the Raspberry Pi computers will prove helpful. Although previous electronics experience is not required, some knowledge of basic electronics is beneficial, especially when venturing out to modify the projects for your own applications.
Over 30 tested and working hardware-based projects are given in the book, covering the use of Wi-Fi, communication with smartphones and with a Raspberry Pi Pico W computer. Additionally, there are Bluetooth projects including elementary communication with smartphones and with the popular Arduino Uno. Both Wi-Fi and Bluetooth are key features of the Raspberry Pi Zero 2 W.
Some of the topics covered in the book are:
Raspberry Pi OS installation on an SD card
Python program creation and execution on the Raspberry Pi Zero 2 W
Software-only examples of Python running on the Raspberry Pi Zero 2 W
Hardware-based projects including LCD and Sense HAT interfacing
UDP and TCP Wi-Fi based projects for smartphone communication
UDP-based project for Raspberry Pi Pico W communication
Flask-based webserver project
Cloud storage of captured temperature, humidity, and pressure data
TFT projects
Node-RED projects
Interfacing to Alexa
MQTT projects
Bluetooth-based projects for smartphone and Arduino Uno communications
The Picon Zero is an add-on for the Raspberry Pi. It has the same size as a Raspberry Pi Zero, making it ideal to function as a pHat. Of course, it can be used on any other Raspberry Pi via a 40-pin GPIO connector.
As well as two full H-Bridge motor drivers, the Picon Zero has several Input/Output pins giving you multiple configuration options. That allows you to easily add outputs or analog inputs to your Raspberry Pi without any complicated software or kernel-specific drivers. At the same time, it opens up 5 GPIO pins from the Raspberry Pi, and it provides the interface for an HC-SR04 ultrasonic distance sensor.
The Picon Zero comes with all components, including the headers and screw terminals, fully soldered. Soldering isn't required. You can use it right out of the box.
Features
pHat format PCB: 65 mm x 30 mm
Two full H-Bridge motor drivers. Drive up to 1.5 A continuously per channel, at 3 V - 11 V.
Each motor output has both a 2-pin male header and a 2-pin screw terminal.
The motors can be powered from the Picon Zero's 5 V or an external power source (3 V - 11 V).
The Picon Zero's 5 V can be selected to be from the Raspberry Pi's 5 V line, or a USB connector on the Picon Zero. That means that you can effectively have 2 USB battery banks: one to power the servos and motors on the Picon Zero and the other to power the Pi.
4 Inputs that can accept up to 5 V. These inputs can be configured as follows:
Digital inputs
Analog inputs
DS18B20
DHT11
6 Outputs that can drive 5 V and be configured as:
Digital Output
PWM Output
Servo
NeoPixel WS2812
All Inputs and Outputs use GVS 3-pin male headers.
4-pin female header that connects directly to an HC-SR04 ultrasonic distance sensor.
8-pin female header for Ground, 3.3 V, 5 V, and 5 GPIO signals allowing you to add their additional features.
Build robust, intelligent machines that combine Raspberry Pi computing power with LEGO components.
The Raspberry Pi Build HAT provides four connectors for LEGO Technic motors and sensors from the SPIKE Portfolio. The available sensors include a distance sensor, a color sensor, and a versatile force sensor. The angular motors come in a range of sizes and include integrated encoders that can be queried to find their position.
The Build HAT fits all Raspberry Pi computers with a 40-pin GPIO header, including – with the addition of a ribbon cable or other extension device — Raspberry Pi 400. Connected LEGO Technic devices can easily be controlled in Python, alongside standard Raspberry Pi accessories such as a camera module.
Features
Controls up to 4 motors and sensors
Powers the Raspberry Pi (when used with a suitable external PSU)
Easy to use from Python on the Raspberry Pi
The Raspberry Pi PoE+ Injector adds Power-over-Ethernet (PoE) functionality to a single port of a non-PoE Ethernet switch, delivering both power and data through one Ethernet cable. It provides a plug-and-play, cost-effective solution for incrementally introducing PoE capability into existing Ethernet networks.
The PoE+ Injector is a single-port, 30 W device suitable for powering equipment compliant with IEEE 802.3af and 802.3at standards, including all generations of Raspberry Pi PoE HATs. It supports network pass-through speeds of 10/100/1000 Mbps.
Note: A separate IEC mains cable is required for operation (not included).
Specifications
Data rate
10/100/1000 Mbps
Input voltage
100 to 240 V AC
Output power
30 W
Power output on pins
4/5 (+), 7/8 (–)
Nominal output voltage
55 V DC
Data connectors
Shielded RJ-45, EIA 568A and 568B
Power connector
IEC c13 mains power input (not included)
Storage humidity
Maximum 95%, non-condensing
Operating altitude
–300 m to 3000 m
Operating ambient temperature
10°C to +50°C
Dimensions
159 x 51.8 x 33.5 mm
Downloads
Datasheet
Program, build, and master over 60 projects with Python
The Raspberry Pi 5 is the latest single-board computer from the Raspberry Pi Foundation. It can be used in many applications, such as in audio and video media centers, as a desktop computer, in industrial controllers, robotics, and in many domestic and commercial applications. In addition to the well-established features found in other Raspberry Pi computers, the Raspberry Pi 5 offers Wi-Fi and Bluetooth (classic and BLE), which makes it a perfect match for IoT as well as in remote and Internet-based control and monitoring applications. It is now possible to develop many real-time projects such as audio digital signal processing, real-time digital filtering, real-time digital control and monitoring, and many other real-time operations using this tiny powerhouse.
The book starts with an introduction to the Raspberry Pi 5 computer and covers the important topics of accessing the computer locally and remotely. Use of the console language commands as well as accessing and using the desktop GUI are described with working examples. The remaining parts of the book cover many Raspberry Pi 5-based hardware projects using components and devices such as
LEDs and buzzers
LCDs
Ultrasonic sensors
Temperature and atmospheric pressure sensors
The Sense HAT
Camera modules
Example projects are given using Wi-Fi and Bluetooth modules to send and receive data from smartphones and PCs, and sending real-time temperature and atmospheric pressure data to the cloud.
All projects given in the book have been fully tested for correct operation. Only basic programming and electronics experience are required to follow the projects. Brief descriptions, block diagrams, detailed circuit diagrams, and full Python program listings are given for all projects described.
These templates are your starting point if you’re building a Raspberry Pi HAT.
Each pack contains six Raspberry Pi B+ templates.
Downloads
Gerber files
Program, build, and master over 50 projects with MicroPython and the RP2040 microprocessor The Raspberry Pi Pico is a high-performance microcontroller module designed especially for physical computing. Microcontrollers differ from single-board computers, like the Raspberry Pi 4, in not having an operating system. The Raspberry Pi Pico can be programmed to run a single task very efficiently within real-time control and monitoring applications requiring speed. The ‘Pico’ as we call it, is based on the fast, efficient, and low-cost dual-core ARM Cortex-M0+ RP2040 microcontroller chip running at up to 133 MHz and sporting 264 KB of SRAM, and 2 MB of Flash memory. Besides its large memory, the Pico has even more attractive features including a vast number of GPIO pins, and popular interface modules like ADC, SPI, I²C, UART, and PWM. To cap it all, the chip offers fast and accurate timing modules, a hardware debug interface, and an internal temperature sensor. The Raspberry Pi Pico is easily programmed using popular high-level languages such as MicroPython and or C/C++. This book is an introduction to using the Raspberry Pi Pico microcontroller in conjunction with the MicroPython programming language. The Thonny development environment (IDE) is used in all the projects described. There are over 50 working and tested projects in the book, covering the following topics: Installing the MicroPython on Raspberry Pi Pico using a Raspberry Pi or a PC Timer interrupts and external interrupts Analogue-to-digital converter (ADC) projects Using the internal temperature sensor and external temperature sensor chips Datalogging projects PWM, UART, I²C, and SPI projects Using Wi-Fi and apps to communicate with smartphones Using Bluetooth and apps to communicate with smartphones Digital-to-analogue converter (DAC) projects All projects given in the book have been fully tested and are working. Only basic programming and electronics experience is required to follow the projects. Brief descriptions, block diagrams, detailed circuit diagrams, and full MicroPython program listings are given for all projects described. Readers can find the program listings on the Elektor web page created to support the book.
The Raspberry Pi Bumper is a snap-on silicone cover that protects the bottom and edges of the Raspberry Pi 5.
Features
One-piece flexible silicone rubber bumper
Enables easy access to the power button
Mounting holes remain accessible underneath the bumper
Downloads
Datasheet
Designed for overclockers and other power users, this fan keeps your Raspberry Pi 4 at a comfortable operating temperature even under heavy load. The temperature-controlled fan delivers up to 1.4 CFM of airflow over the processor, memory, and power management IC. The bundled heatsink (18 x 8 x 10 mm) with self-adhesive pad improves heat transfer from the processor. The Raspberry Pi 4 Case Fan works with Raspberry Pi 4 and the official Raspberry Pi 4 case.
