Difference between revisions of "Arduino"
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[[Image:Elphel-arduino.jpeg|thumb|Elphel NC353L-10369 camera with Arduino for easy Duemilanove]] | [[Image:Elphel-arduino.jpeg|thumb|Elphel NC353L-10369 camera with Arduino for easy Duemilanove]] | ||
+ | [[Image:ArduinoDiecimilaComponents.jpg]] | ||
+ | |||
+ | ==Preamble== | ||
[http://arduino.cc/en/Main/ArduinoBoardDuemilanove Arduino] is an open-source electronics prototyping platform based on flexible, easy-to-use hardware and software. | [http://arduino.cc/en/Main/ArduinoBoardDuemilanove Arduino] is an open-source electronics prototyping platform based on flexible, easy-to-use hardware and software. | ||
− | Here is a simple example of how to use Arduino with Elphel cameras. I connected a PIR (Passive | + | Here is a simple example of how to use Arduino with Elphel cameras. I connected a PIR (Passive Infrared motion sensor) and a button to my Arduino. Motion detection will trigger recording on CF for a minute and the button will store a full resolution snapshot on CF. |
As motion detection or button pressure is detected on Arduino it send a _shell command_ to the camera over usb-serial connection. So it is easy to automate everything the camera can do. | As motion detection or button pressure is detected on Arduino it send a _shell command_ to the camera over usb-serial connection. So it is easy to automate everything the camera can do. | ||
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microcom -s 9600 /dev/ttyUSB0 | sh | microcom -s 9600 /dev/ttyUSB0 | sh | ||
− | + | ==Configuring your camera firmware== | |
+ | ===Getting the SDK=== | ||
+ | Please refer to [[Elphel Software Kit for Ubuntu]] for SDK installation | ||
+ | |||
+ | ===Modify the kernel config=== | ||
+ | go to the source directory for example ~/elphel_projects/elphel353-8.0.8.29/elphel353 | ||
+ | |||
+ | sed s/"# CONFIG_USB_SERIAL_FTDI_SIO is not set"/"CONFIG_USB_SERIAL_FTDI_SIO=y"/g os/linux-2.6/.config > os/linux-2.6/.config__ | ||
+ | mv os/linux-2.6/.config__ os/linux-2.6/.config | ||
+ | |||
+ | Creating /dev/ttyUSB0 is not necessary, it was already done for compass and GPS modules, but if you need to add some /dev file, it can be done in ~/elphel353-8.0.4.3/elphel353/packages/devices/elphel/Makefile . | ||
+ | |||
+ | ===Build the firmware=== | ||
+ | Just: | ||
+ | make | ||
+ | |||
+ | ==Arduino source code== | ||
+ | |||
//the time we give the sensor to calibrate (10-60 secs according to the datasheet) | //the time we give the sensor to calibrate (10-60 secs according to the datasheet) | ||
int calibrationTime = 10; | int calibrationTime = 10; | ||
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} | } | ||
− | + | ==On the camera== | |
+ | Now that your camera have support for FTDI driver you can plug the Arduino and execute on the camera: | ||
+ | microcom -s 9600 /dev/ttyUSB0 | sh | ||
+ | |||
+ | This can be also done at boot from /etc/inittab or /etc/launcher.conf.xml |
Latest revision as of 02:43, 28 June 2010
Contents
Preamble
Arduino is an open-source electronics prototyping platform based on flexible, easy-to-use hardware and software.
Here is a simple example of how to use Arduino with Elphel cameras. I connected a PIR (Passive Infrared motion sensor) and a button to my Arduino. Motion detection will trigger recording on CF for a minute and the button will store a full resolution snapshot on CF.
As motion detection or button pressure is detected on Arduino it send a _shell command_ to the camera over usb-serial connection. So it is easy to automate everything the camera can do.
On the camera I only enabled FTDI driver in the kernel and run microcom to send output to the shell:
microcom -s 9600 /dev/ttyUSB0 | sh
Configuring your camera firmware
Getting the SDK
Please refer to Elphel Software Kit for Ubuntu for SDK installation
Modify the kernel config
go to the source directory for example ~/elphel_projects/elphel353-8.0.8.29/elphel353
sed s/"# CONFIG_USB_SERIAL_FTDI_SIO is not set"/"CONFIG_USB_SERIAL_FTDI_SIO=y"/g os/linux-2.6/.config > os/linux-2.6/.config__ mv os/linux-2.6/.config__ os/linux-2.6/.config
Creating /dev/ttyUSB0 is not necessary, it was already done for compass and GPS modules, but if you need to add some /dev file, it can be done in ~/elphel353-8.0.4.3/elphel353/packages/devices/elphel/Makefile .
Build the firmware
Just:
make
Arduino source code
//the time we give the sensor to calibrate (10-60 secs according to the datasheet) int calibrationTime = 10; //the time when the sensor outputs a low impulse long unsigned int lowIn; //the amount of milliseconds the sensor has to be low //before we assume all motion has stopped long unsigned int pause = 60000; boolean lockLow = true; boolean takeLowTime; int pirPin = 3; //the digital pin connected to the PIR sensor's output int ledPin = 13; int inPin = 2; // choose the input pin (for a pushbutton) int val = 0; // variable for reading the pin status bool pushed = false; // void setup(){ Serial.begin(9600); pinMode(pirPin, INPUT); pinMode(inPin, INPUT); // declare pushbutton as input pinMode(ledPin, OUTPUT); digitalWrite(pirPin, LOW); delay(50); //give the sensor some time to calibrate Serial.print("#calibrating sensor "); for(int i = 0; i < calibrationTime; i++){ Serial.print("."); delay(1000); } Serial.println("# done"); Serial.println("#SENSOR ACTIVE"); delay(50); } // void loop(){ if(digitalRead(pirPin) == HIGH){ digitalWrite(ledPin, HIGH); //the led visualizes the sensors output pin state if(lockLow){ //makes sure we wait for a transition to LOW before any further output is made: lockLow = false; Serial.println("echo 'status; start; status=/var/tmp/camogm.status' > /var/state/camogm_cmd"); delay(50); } takeLowTime = true; } if(digitalRead(pirPin) == LOW){ digitalWrite(ledPin, LOW); //the led visualizes the sensors output pin state if(takeLowTime){ lowIn = millis(); //save the time of the transition from high to LOW takeLowTime = false; //make sure this is only done at the start of a LOW phase } //if the sensor is low for more than the given pause, //we assume that no more motion is going to happen if(!lockLow && millis() - lowIn > pause){ //makes sure this block of code is only executed again after //a new motion sequence has been detected lockLow = true; Serial.println("echo 'status; stop; status=/var/tmp/camogm.status' > /var/state/camogm_cmd"); //output delay(50); } } // button handler val = digitalRead(inPin); // read input value if (val == HIGH) { // check if the input is HIGH (button released) if(pushed) { pushed = false; } } else { if(!pushed) { pushed = true; Serial.println("wget http://127.0.0.1/snapfull.php -O /var/hdd/snapfull`date +%s`.jpg"); } } }
On the camera
Now that your camera have support for FTDI driver you can plug the Arduino and execute on the camera:
microcom -s 9600 /dev/ttyUSB0 | sh
This can be also done at boot from /etc/inittab or /etc/launcher.conf.xml