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In a three-day camp, teens learn to program and build interactive electronics using Arduino microcontrollers.
The power supply wiring on the back of the plywood board that carries the amplifier, batteries and Arduino. There's a terminal block that feeds power from the batteries to the Arduino and he amplifier. Also shown is the sensor board, with three reflective opto-sensors.
Fiddling about with a Basic Stamp2 microcontroller talking via serial cable and Keyspan serial-to-USB to MacBS2, a Mac OS X app for writing PBasic programs and talking to the BS.
Expanding on Microchip’s existing 8-bit PIC® microcontroller-based mTouch development tools for capacitive touch, the PICDEM Touch Sense 2 Demo Board enables designers to implement this leading-edge user interface with Microchip’s wide portfolio of 16-bit PIC24F MCUs. Equipped with capacitive touch-sensing keys and sliders, the board allows designers to evaluate this interface in their applications using the Windows-based mTouch Diagnostic Tool, an easy-to-use Graphical User Interface (GUI) that is included in the mTouch Sensing Solution SDK. The software libraries, source code and other support materials that come with the board further shorten development time and reduce design costs.
. Expanding on Microchip’s existing 8-bit PIC® microcontroller-based mTouch development tools for capacitive touch, the PICDEM Touch Sense 2 Demo Board enables designers to implement this leading-edge user interface with Microchip’s wide portfolio of 16-bit PIC24F MCUs. Equipped with capacitive touch-sensing keys and sliders, the board allows designers to evaluate this interface in their applications using the Windows-based mTouch Diagnostic Tool, an easy-to-use Graphical User Interface (GUI) that is included in the mTouch Sensing Solution SDK. The software libraries, source code and other support materials that come with the board further shorten development time and reduce design costs.
. Expanding on Microchip’s existing 8-bit PIC® microcontroller-based mTouch development tools for capacitive touch, the PICDEM Touch Sense 2 Demo Board enables designers to implement this leading-edge user interface with Microchip’s wide portfolio of 16-bit PIC24F MCUs. Equipped with capacitive touch-sensing keys and sliders, the board allows designers to evaluate this interface in their applications using the Windows-based mTouch Diagnostic Tool, an easy-to-use Graphical User Interface (GUI) that is included in the mTouch Sensing Solution SDK. The software libraries, source code and other support materials that come with the board further shorten development time and reduce design costs.
. Expanding on Microchip’s existing 8-bit PIC® microcontroller-based mTouch development tools for capacitive touch, the PICDEM Touch Sense 2 Demo Board enables designers to implement this leading-edge user interface with Microchip’s wide portfolio of 16-bit PIC24F MCUs. Equipped with capacitive touch-sensing keys and sliders, the board allows designers to evaluate this interface in their applications using the Windows-based mTouch Diagnostic Tool, an easy-to-use Graphical User Interface (GUI) that is included in the mTouch Sensing Solution SDK. The software libraries, source code and other support materials that come with the board further shorten development time and reduce design costs.
Expanding on Microchip’s existing 8-bit PIC® microcontroller-based mTouch development tools for capacitive touch, the PICDEM Touch Sense 2 Demo Board enables designers to implement this leading-edge user interface with Microchip’s wide portfolio of 16-bit PIC24F MCUs. Equipped with capacitive touch-sensing keys and sliders, the board allows designers to evaluate this interface in their applications using the Windows-based mTouch Diagnostic Tool, an easy-to-use Graphical User Interface (GUI) that is included in the mTouch Sensing Solution SDK. The software libraries, source code and other support materials that come with the board further shorten development time and reduce design costs.
Product image of components from the Jennic range - www.sequoia.co.uk/components/manufacturer_list.php?m=12&a...
Jennic is a market leader in ZigBee, 6LoWPAN, IEEE802.15.4 wireless microcontrollers, modules and evaluation kits.
DSP microcontroller hand-soldered to the NUE-PSK circuit board. The chip is a 64-lead TQFP (thin quad flatpack), 10mm square. The lead pitch is 0.5mm, and each lead is 0.22mm wide.
Product image of components from the Jennic range - www.sequoia.co.uk/components/manufacturer_list.php?m=12&a...
Jennic is a market leader in ZigBee, 6LoWPAN, IEEE802.15.4 wireless microcontrollers, modules and evaluation kits.
Product image of components from the Jennic range - www.sequoia.co.uk/components/manufacturer_list.php?m=12&a...
Jennic is a market leader in ZigBee, 6LoWPAN, IEEE802.15.4 wireless microcontrollers, modules and evaluation kits.
Product image of components from the Jennic range - www.sequoia.co.uk/components/manufacturer_list.php?m=12&a...
Jennic is a market leader in ZigBee, 6LoWPAN, IEEE802.15.4 wireless microcontrollers, modules and evaluation kits.
Atmel Studio 7 is the integrated development platform (IDP) for developing and debugging Atmel® SMART ARM®-based and Atmel AVR® microcontroller (MCU) applications. Studio 7 supports all AVR and Atmel SMART MCUs. The Atmel Studio 7 IDP gives you a seamless and easy-to-use environment to write, build and debug your applications written in C/C++ or assembly code. It also connects seamlessly to Atmel debuggers and development kits.
Additionally, Atmel Studio includes Atmel Gallery, an online apps store that allows you to extend your development environment with plug-ins developed by Atmel as well as by third-party tool and embedded software vendors. Atmel Studio 7 can also able seamlessly import your Arduino sketches as C++ projects, providing a simple transition path from Makerspace to Marketplace.Atmega-8 based Development BoardAtmega-32 Development Board for EmbeddedMicro-controllers-Basic Introduction TutorialsFlowcode Programming and Simulation TutorialPrior to installation of AVR Studio you have to install the compiler WinAVR. This will allow AVR Studio to detect the compiler.
Step 1: Download the setup file from Atmel site.There are two option for download A. Atmel Studio 7.0 (build 790) web installer B. Atmel Studio 7.0 (build 790) offline installerUser should select as per their convinience.
Step 2: After selection you will be prompted to fill a form.Complete the form and download link will appear.Click download then wait for download to complete.Step 3: Double click the Installer/Setup file and installation will start automatically.
CONTINUE READING »
via IngenuityDias www.ingenuitydias.com/2016/03/avr-studio-7-tutorial-insta...
The Basic I/O Shield is designed to provide a range of input/output devices suitable for beginners learning about microcontrollers and various types of I/O devices, or for use by more advanced user to provide inputs or outputs for their own projects.
The Basic I/O Shield provides simple digital input devices such as switches and buttons, and digital output devices such as discrete LEDs and high current open FET drivers. It provides more advanced devices such as an I2C EEPROM, an I2C temperature sensor, and organic LED graphic display. A potentiometer is also provided for use as an analog input device.
store.digilentinc.com/chipkit-basic-i-o-shield-input-outp...
A spare part for a Nokia 1202 mobile phone, which is a handy 96x68 pixel display for microcontrollers. The interface is 9-bit SPI at 3.3V levels and uses an STE2007 chip, bonded directly to the glass. I've got it wired up to the MSP430 LaunchPad board, partly because that board is 3.3V and partly because there's a handy bit of example code, here: dangerousprototypes.com/forum/viewtopic.php?f=19&t=3486
Huss had rigged up a Nintendo DS touch-screen (available as an inexpensive spare part) to an Arduino. The Arduino was running a simple program to read X,Y co-ordinates from the device, and send them to a host computer via USB.
The SBS-52A single-board computer featured in www.flickr.com/photos/toonfox42/8895027050/in/set-7215763... hooked up and working.
Microchip Sets New Benchmark for Low-Power Microcontrollers (MCUs); Significantly Expands Enhanced 8-bit PIC® MCU Portfolio
Jacks for the HiViz trigger outputs to camera and flash, input from Photogate drop sensor, and power output to the solenoid valve (under control of the BS2 microcontroller).
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I designed and built a passive infrared trigger for my Canon EOS 5D camera (will work with any camera with a remote shutter release socket) to take pictures when something (an animal) sets off the PIR sensor. This will allow me to set the camera up to automatically capture anythng that moves in front of the sensor. I used a microcontroller to control the camera wake up and shutter release relays. This gives me the ability to control the frequency and number of shots. For the prototype I trigger the wake up relay for 300ms then the shutter release relay for 300ms followed by a 300ms pause before checking the input again to see if there is still movement in front of the PIR sensor. I also put a long delay (1 second) after 5 continuous shots. Depending on results I may replace this long delay with a wait until the PIR is no longer being triggered to prevent too many pictures of one event if the animal stays in range of the PIR sensor for a while. The cool thing is that the camera can go into sleep mode allowing the battery to last for days as the circuit wakes the camera up when movement is detected.
Microchip Technology's MCP6051/2/4 (MCP605X), MCP6061/2/4 (MCP606X) and MCP6071/2/4 (MCP607X) op amps feature offset voltages of just 150 microvolts and are well suited for applications requiring low power consumption, low-voltage operation and high precision, such as those in the industrial, medical, consumer and other markets
Arduino controllers are very powerful, but it's easy to get started programming them-especially with our kits.
I just received these 2x16 LCDs (and one 2x40) white on blue with LED backlight. This is a setup for using it in 4bit mode with an I2C IO expander. (Excuse the bad pict, blue LCDs are a pain to shoot)
Webcam -> Processing -> Arduino -> Peggy. :)
15 FPS "Real-time" video on the Peggy 2.
This is my Arduino-like ATmega168 on its breakout board-- performing serial-TWI conversion.
Read more about this project here.