The current tutorial explains how to take the most of the IntelĀ® Galileo development board by using on it the Arduino and Raspberry Pi shields and modules designed by Cooking Hacks. The platform is easy to use for new designers and for those looking to take designs to the next level. This platform provides the ease of Intel architecture development through support for the Microsoft Windows, Mac OS and Linux host operating systems.
The e-Health Sensor Shield V2.0 allows Arduino, Raspberry Pi and Intel Galileo users to perform biometric and medical applications using 10 different sensors: pulse, electrocardiogram (ECG), airflow (breathing), oxygen in blood (SPO2), glucometer, body temperature, blood pressure (sphygmomanometer), galvanic skin response (GSR - sweating), patient position (accelerometer) and muscle/eletromyography sensor (EMG).
This module offers GPRS connection to your Arduino/RasberryPi/IntelGalileo board. In this tutorial you will find code examples to make a lost call or to send SMS. It is possible to use this shield in standalone mode.
The Multiprotocol Radio Shield is an interconnection shield for Arduino, Raspberry Pi and Intel Galileo, and was designed to connect two communication modules at the same time. This that means a lot of possibilities and applications can be made using the cooking-hacks modules.
This guide describes all features of the RS-485 module. RS-485 is the most versatile communication standard. The RS-485 module for Arduino, Raspberry Pi and Intel Galileo allows users to perform industrial and domotic applications.
In this tutorial you can find a detailed description of the RS-232 module. The RS-232 standard is still used to connect industrial equipment (such as PLCs), console ports and special purpose equipment.
This tutorial describes all features of the CAN Bus module which has been mainly designed to perform vehicle diagnostics in real time. CAN is a multi-master broadcast serial bus standard for connecting electronic control units (ECUs). This module also allows the interconnection of different devices to work with this communications protocol for applications such as industrial networks, home automation, etc.
In this tutorial you can find a detailed description of the 4-20mA (Current Loop) Board. The 4-20 mA current loop is one of the most robust sensor signaling standard. Current loops are ideal for data transmission because of their inherent insensitivity to electrical noise.
This tutorial describes all features of the Modbus module. Modbus is a serial communications protocol originally published by Schneider Electric in 1979 for use with their programmable logic controllers (PLCs). Modbus can be operated physically on the RS-485 and RS-232 modules.
The GPS module is a small electronic circuit that allows to connect to your Intel Galileo board to get position and altitude. It uses the standard NMEA protocol to transmit the position data via serial port. It will allow you to get as well as speed, date and time on UTC (Universal Time Coordinated).
This shield integrates the SIM908 module which counts with both GPRS and GPS technologies. It allows to easily perform realtime tracking applications. It is possible to use this shield in standalone mode.
Bluetooth Module is able to be plugged into the XBee Shield and get a serial communication between the computer and an Intel Galileo through Bluetooth protocol. In this tutorial we'll use an Intel Galileo with bluetooth module (Connected using a XBee shield) and a PC with a bluetooth USB dongle (Linksys Bluetooth Adapter).
The tutorial describes some features of Bluetooth module PRO for Arduino / Raspberry Pi which has been mainly designed to discover high amount of bluetooth devices in a variable area.The Bluetooth PRO module has been mainly designed to discover high amount of bluetooth devices along with its RSSI and Class of Device (CoD). It can be connected in a Xbee shield to work.
The tutorial describes how to set up and use the Radiation Sensor Board two main parts, the power circuit and the signal circuit. The power part is used to provide the voltage necessary for the tube (400V - 1000V) and the signal circuit is used to adapt the pulses output from the tube and connect it to the input of the microcontroller.