Difference between revisions of "Raspberry Pi"
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<br/> HW: https://www.argon40.com/learn/index.php/2020/03/06/a-comprehensive-guide-on-raspberry-pi-3-and-raspberry-pi-zero-and-zero-w-gpio-pinout/ | <br/> HW: https://www.argon40.com/learn/index.php/2020/03/06/a-comprehensive-guide-on-raspberry-pi-3-and-raspberry-pi-zero-and-zero-w-gpio-pinout/ | ||
<br/> JW: https://www.raspberrypi.org/documentation/usage/gpio/ | <br/> JW: https://www.raspberrypi.org/documentation/usage/gpio/ | ||
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+ | <br/> SF: With the gpiozero library you will by default want to reference the pin number as in GPIOx where x is the pin you define in software. Example: LED(5) in Software; connect to GPIO5 on the Pi Zero header. | ||
=== Setting up the OS and Python === | === Setting up the OS and Python === |
Revision as of 17:36, 20 November 2020
There are different version of the Raspberry Pi https://www.raspberrypi.org/, e.g.
- Raspberry Pi 4 Model B
- Raspberry Pi Zero W
- Raspberry Pi Zero
- Raspberry Pi 400 (https://www.sketching-with-hardware.org/wiki/Raspberry_Pi400)
- Raspberry Pi 3 Model B
The Raspberry Pi is a Linux computer that has a multitude of connectors and in particular, it provides GPIO pins. The connector (HAT) provides an easy way to add your own sensors and actuators and there are many boars that can be connected.
Audio input and output are not very good, hence we recommend using a USB Sound Adapter (the 5€ versions work very well).
For programming, we will use python.
For controlling the Pins on the Raspberry Pi, you may want to look at the following library
- RPi.GPIO https://pypi.org/project/RPi.GPIO/
- Examples of RPi.GPIO https://sourceforge.net/p/raspberry-gpio-python/wiki/Examples/
- gpiozero access to GPIO https://gpiozero.readthedocs.io/en/stable/
Web server on the Raspberry Pi
- https://towardsdatascience.com/python-webserver-with-flask-and-raspberry-pi-398423cc6f5d
- https://randomnerdtutorials.com/raspberry-pi-web-server-using-flask-to-control-gpios/
Contents
Resources
Pinout of Pi Zero
physical connections
JL: https://peppe8o.com/raspberry-pi-zero-pinout/
CR: https://de.pinout.xyz/pinout/io_pi_zero
HW: https://www.argon40.com/learn/index.php/2020/03/06/a-comprehensive-guide-on-raspberry-pi-3-and-raspberry-pi-zero-and-zero-w-gpio-pinout/
JW: https://www.raspberrypi.org/documentation/usage/gpio/
SF: With the gpiozero library you will by default want to reference the pin number as in GPIOx where x is the pin you define in software. Example: LED(5) in Software; connect to GPIO5 on the Pi Zero header.
Setting up the OS and Python
NOOBS
configure
JL: https://www.tutorialspoint.com/python/python_environment.htm
CR: https://learn.adafruit.com/setting-up-a-raspberry-pi-with-noobs/download-noobs
HW: https://www.raspberrypi.org/help/noobs-setup./
JW: https://www.raspberrypi.org/documentation/installation/noobs.md
SG: https://medium.com/@nikosmouroutis/how-to-use-atom-with-your-raspberry-pi-through-sftp-382c43176a9e
SF: https://www.raspberrypi.org/software/
Access to GPIO
JL: http://codefoster.com/pi-basicgpio/
CR: https://fedoramagazine.org/raspberry-pi-zero-gpio-fedora/
HW: https://webnist.de/raspberry-pi-zero-gpio-pins-ueber-den-desktop-steuern/
SG: https://github.com/fivdi/onoff
Blinking an LED
JL: https://raspberrypihq.com/making-a-led-blink-using-the-raspberry-pi-and-python/
CR: https://fedoramagazine.org/raspberry-pi-zero-gpio-fedora/
HW: https://webnist.de/raspberry-pi-zero-gpio-pins-ueber-den-desktop-steuern/
JW: http://www.heidislab.com/tutorials/getting-started-with-raspberry-pi-led-blinking-on-raspberry-pi-zero
Reading a Pin
JL: http://raspberry.io/projects/view/reading-and-writing-from-gpio-ports-from-python/
CR: https://learn.sparkfun.com/tutorials/raspberry-gpio/all
HW: https://mjrobot.org/rpi-gpiozero/
SG: https://tutorials-raspberrypi.de/raspberry-pi-gpio-erklaerung-beginner-programmierung-lernen/
Runing a Webserver that access GPIO
JL: https://towardsdatascience.com/python-webserver-with-flask-and-raspberry-pi-398423cc6f5d
CR: https://www.e-tinkers.com/2018/04/how-to-control-raspberry-pi-gpio-via-http-web-server/
HW: https://hackaday.io/project/173322-controlling-gpio-outputs-using-a-web-interface-wit
JW: https://www.youtube.com/watch?v=c6FOpPXbLjs
SG: https://randomnerdtutorials.com/raspberry-pi-web-server-using-flask-to-control-gpios/
Restful API
JL: https://sites.google.com/site/cartwrightraspberrypiprojects/home/other-projects/rest-api
CR: https://docs.dataplicity.com/docs/control-gpios-using-rest-api
HW: https://www.youtube.com/watch?v=JZfevVG-VuA&list=PLLIDdNg0t5ceg3mI3vn0YJocJ4ndMtM98&index=4&t=0s
SG: https://tutorials-raspberrypi.de/raspberry-pi-nodejs-webserver-installieren-gpios-steuern/
Description of the components
JL: https://www.adafruit.com/product/3411
CR: https://computer.howstuffworks.com/raspberry-pi2.htm
HW: https://learn.adafruit.com/introducing-the-raspberry-pi-zero
JW: https://www.youtube.com/watch?v=WJdQ4rknBX0
Project Ideas
SG
mindSat:
A small portable gadget. Which can record sensor data and give feedback to a user. Mind satisfaction for your offices days.
It’s hard to do small exercises, often we find excuses to not do it. Concentrated breathing can help your brain to relax, or focusing on small things can reduce stress. Using those informations to create short (~ 5min) exercises.
JL
Home Office Buddy:
A speaker communicating in a pleasant way with the target person in order to minimize a possible social isolation and encourage the keeping of important routines & daily structures in order to maintain a certain productivity during a working day.
Example: suggest unplanned short breaks if the target person is showing a lack of concentration measured by a certain level of body movement.
JP
Problem: too much sitting while working in the office
Idea: adjustable desk
Sensors: on the chair, to check, if the user is sitting and how long
Notification: User gets a message after a certain time, that the desk will rise for min. 30 minutes. After that time the desk can be lowerd again, if wished. The Sensor will messures again.
Gamification: a little "stand-up-figure" will be on the desk and will stand up, if the desk is rised. Will be collapse, if the desk is lowered.
CR
Problem: Tension due to prolonged sitting and incorrect sitting positions (e.g. crooked shoulders)
Sensors: Kinect for analysis of posture, sensors that measure the tension in the neck
The longer one maintains a bad sitting position, the older/bent an avatar becomes on the screen. Through movement the avatar becomes younger/upright again.
YS
WALL-E: your digital stress cleaner
Features
- The buggy has two “hands” and one trash can
- Users’ stress detection: EDA/HRV
- If stressful: The buggy will
- search for the smartphone (RFID or GPS)
- steal the smartphone
- drop it into the trash can
- If user calms down: be allowed to use smartphone
JW
Problem: ① Uncomfortable working environment in aspects of lighting and air quality; ② Avoidable disturbance by colleges, etc.; ③ Remaining stationary for too long
Solution: ① Automatic adjustable light, automatic jalousie roller, automatic humidifier, LED as indicator next to windows; ② Display as door sign; ③ Speaker with a switch as indicator
Sensor: Temperature and humidity sensor Bme280, light sensor Tsl2561, CO2 sensor, motion sensor
HW
Problem: Pain in the hand and wrist due to consistent movement or incorrect hand/arm position
Sensors: e.g. Leap Motion for motion and posture detection, keyboard/mouse to track activity (?)
Vibration of the mouse/keyboard if the same position was kept for too long or no pause was made. A visualization of an inflammation (red pulsating circles) is displayed, which gets worse/better depending on user behavior. This warns the user when his hand position is worsening. The user may choose to be prevented from continuing to work or not.