7 changed files with 159 additions and 113 deletions
--- a/docs/circuit/build_circuit_diagram.sh
+++ b/docs/circuit/build_circuit_diagram.sh
@ -0,0 +1,6 @@
 #!/bin/sh
 trap 'rm -f circuit.aux circuit.log circuit.pdf' 0
 # create circuit.png
 pdflatex -shell-escape circuit
--- a/docs/circuit/circuit.md
+++ b/docs/circuit/circuit.md
@ -0,0 +1,59 @@
 # Space Status Circuit
 The status of Krautspace's door is captured, displayed and broadcast into the
 internet by an Arduino, a Raspberry Pi, and some circuitry. The following
 diagram shows a detailed representation of the circuit.
 The Arduino is (and should be only) responsible for the sensor read out and the
 local status display (traffic light).
 The Raspberry Pi is (and should be only) responsible for grabbing the status
 from the Arduino and broadcasting it to the internet.
 ![Circuit diagram](circuit.png)
 ## Sensor
 The locked-unlocked-state of the door is determined by a reed switch
 embedded in the strikeplate hole, that is triggered by a magnet glued to the
 lock's deadbolt.
 The switch is connected to the Arduino via two wires.
 ## Arduino
 The system uses an Arduino Duemilanove. It monitors the state of the reed switch
 and controls three LEDs on the breadboard.
 The reed switch is connect to a 5V pin and pin D13. Note, that pin D13 also
 controls the on-board LED, so whenever the switch is in the closed state (DOES
 THIS CORRESPOND TO THE DOOR BEING IN THE CLOSED STATE?), the on-board LED is on.
 Three LEDs, green, yellow, and red, on a breadboard have their anodes connected
 to pins D10, D11, and D12 and their cathodes to GND.
 The Arduino gets its power via a USB cable from the Raspberry Pi. This gives
 them with a common ground. If this were not the case, the connection between
 their grounds via the breadboard, as it exists right now and is shown in the
 diagram, would be required.
 The logic of how the state of the reed switch is converted into the state of the
 LEDs is discussed in the documentation of the Arduino software.
 ## Circuit
 The circuit uses 120Ω series resistors for the LEDs.
 The circuit also includes a voltage divider for the Raspberry Pi's connection
 to the anode of the green LED. The voltage is reduced from 5V to
 1.8kΩ/(1.8kΩ + 2.1kΩ) * 5V ~= 0.5 * 5V ~= 2.5V.
 ## Raspberry Pi
 The system uses a Raspberry Pi Model 3.
 The Raspberry Pi grabs the state of the green LED from its anode on the
 breadboard. This is done via pin GPIO18.
 The logic of how this state is communicated to the internet is discussed in the
 documentation for the Raspberry Pi software.
--- a/docs/circuit/circuit.png
+++ b/docs/circuit/circuit.png
--- a/docs/circuit/circuit.tex
+++ b/docs/circuit/circuit.tex
@ -0,0 +1,94 @@
 \documentclass[border=10, convert={outfile=\jobname.png}]{standalone}
 \usepackage[european resistor]{circuitikz}
 \usetikzlibrary{fit, shapes.misc}
 \usepackage{siunitx}
 \begin{document}
 \begin{circuitikz}[]
  % Raspberry Pi 3B
  \draw (0.5, 3.5) rectangle (3, -2);
  \node[right] at (1, 3) {\textbf{Raspi}};
  \draw (3.5, 2) to [short] (2.5, 2) node [left] {GND};
  \draw (3.5, 0) to [short] (2.5, 0) node [left] {GPIO18};
  \draw (1.75, -1.5) node [above] {USB}
    to [short] (1.75, -2.5);
  % Bread Board
  \draw (4, 3.5) rectangle (11.5, -4);
  \node[right] at (4.5, 3) {\textbf{Breadboard}};
  \draw (3.5, 2) to [short] (4.5, 2) node [circ] {}
    to [short] (6.5, 2) node [circ] {}
    to [short] (12, 2);
  \draw (3.5, 0) to [short] (4.5, 0) node [circ] {}
    to [R, l=$\SI{1.8}{\kilo\ohm}$] (6.5, 0)
    to [short] (10.5, 0);
  \draw (12, 1)
    to [short] (10.5, 1)
    to [R, l_=$\SI{120}{\ohm}$] (8.5, 1)
    to [empty led, l_=Green] (6.5, 1) node [circ] {};
  \draw (12, -1.5)
    to [short] (10.5, -1.5)
    to [R, l_=$\SI{120}{\ohm}$] (8.5, -1.5)
    to [empty led, l_=Yellow] (6.5, -1.5) node [circ] {};
  \draw (12, -3)
    to [short] (10.5, -3)
    to [R, l_=$\SI{120}{\ohm}$] (8.5, -3)
    to [empty led, l_=Red] (6.5, -3) node [circ] {};
  \draw (11, -3) to [short] (12, -3);
  \draw (4.5, 2) to [R, l=$\SI{2.1}{\kilo\ohm}$] (4.5, 0);
  \draw (6.5, 2) to [short] (6.5, -3);
  \draw (10.5, 1) node [circ] {}
    to [short] (10.5, 0);
  % Arduino Duemilanove
  \draw (12.5, 3.5) rectangle (16, -3.5);
  \node[right] at (13, 3) {\textbf{Arduino}};
  \draw (12, 2) to [short] (13, 2) node [right] {GND};
  \draw (12, 1) to [short] (13, 1) node [right] {D10};
  \draw (12, -1.5) to [short] (13, -1.5) node [right] {D11};
  \draw (12, -3) to [short] (13, -3) node [right] {D12};
  \draw (16.5, 2) to [short] (15.5, 2) node [left] {\SI{5}{\volt}};
  \draw (16.5, 0) to [short] (15.5, 0) node [left] {D13};
  \draw (15, -3) node [above] {USB}
    to [short] (15, -4);
  % Sensor
  \draw (17, 3.5) rectangle (19.5, -0.5);
  \node[right] at (17.5, 3) {\textbf{Sensor}};
  \draw (16.5, 2) to [short] (18, 2);
  \draw (16.5, 0) to [short] (18, 0);
  \draw (18, 2) to [normal open switch, name=switch] (18, 0);
  \node [rounded rectangle, line width=1pt, draw, fit=(switch), inner ysep=1pt, inner xsep=10, rotate=90] at (switch.center) {};
  % USB cable
  \draw (1.75, -2.5)
    to [short] (1.75, -5)
    to [short, l=Power for Arduino] (15, -5)
    to [short] (15, -4);
 \end{circuitikz}
 \end{document}
 %%% Local Variables:
 %%% coding: utf-8
 %%% mode: latex
 %%% TeX-engine: xetex
 %%% End:
--- a/docs/hardware/.gitignore
+++ b/docs/hardware/.gitignore
@ -1,3 +0,0 @@
 circuits.aux
 circuits.log
 circuits.pdf
--- a/docs/hardware/build_circuits.sh
+++ b/docs/hardware/build_circuits.sh
@ -1 +0,0 @@
 xelatex circuits.tex
--- a/docs/hardware/circuits.tex
+++ b/docs/hardware/circuits.tex
@ -1,109 +0,0 @@
 \documentclass[a4paper]{scrartcl}
 \usepackage{tikz}
 \usepackage[european resistor]{circuitikz}
 \usepackage{siunitx}
 \begin{document}
 \begin{figure}
  \begin{circuitikz}
    % Raspberry Pi
    \draw (0.5, -0.5) rectangle (3, 3.5);
    \node at (1.5, 3) {\textbf{RPi}};
    \draw (3.5, 2) to [short] (2.5, 2) node [left] {GND};
    \draw (3.5, 0) to [short] (2.5, 0) node [left] {GPIO18};
    % Bread Board 1
    \draw (4, -0.5) rectangle (7.5, 3.5);
    \node at (5, 3) {\textbf{BB1}};
    \draw (3.5, 2) to [short] (4.5, 2) node [circ] {}
      to [short] (5.5, 2) node [circ] {}
      to [short] (8, 2);
    \draw (3.5, 0) to [short] (4.5, 0) node [circ] {}
      to [short] (5.5, 0) node [circ] {}
      to [R, l=$R_2$] (7.5, 0)
      to [short] (8, 0);
    \draw (4.5, 2) to [push button] (4.5, 0);
    \draw (5.5, 2) to [R, l=$R_1$] (5.5, 0);
    % Bread Board 2
    \draw (8.5, -3.5) rectangle (11.5, 3.5);
    \node at (10, 3) {\textbf{BB2}};
    \draw (8, 2) to [short] (9, 2) node [circ] {}
      to [short] (12, 2);
    \draw (9, 1) node [circ] {} to [empty led] (11, 1) node [circ] {}
      to [short] (12, 1);
    \draw (8, 0) to [short] (9.5, 0)
      to [empty led] (11.5, 0)
      to [short] (12, 0);
    \draw (9, -1) node [circ] {} to [R, l=$R_3$] (11, -1)
      to [short] (12, -1);
    \draw (10, -2) to [short] (12, -2);
    \draw (11, -3) to [short] (12, -3);
    \draw (9, 4) to [short] (9, -1)
      to [R, l=$R_4$] (9, -3)
      to [short] (9, -4);
    \draw (10, -2) to [short] (10, -4);
    \draw (11, 4) to [short] (11, 1);
    \draw (11, -3) to [short] (11, -4);
    % Door
    \draw (8.5, 4.5) rectangle (11.5, 6.5);
    \node at (9.5, 6) {\textbf{Door}};
    \draw (9, 5) to [empty led] (11, 5);
    \draw (9, 5) to [short] (9, 4);
    \draw (11, 5) to [short] (11, 4);
    % ADMN
    \draw (12.5, -3.5) rectangle (15, 3.5);
    \node at (13.5, 3) {\textbf{Arduino}};
    \draw (12, 2) to [short] (13, 2) node [right] {GND};
    \draw (12, 1) to [short] (13, 1) node [right] {D12};
    \draw (12, 0) to [short] (13, 0) node [right] {D10};
    \draw (12, -1) to [short] (13, -1) node [right] {A0};
    \draw (12, -2) to [short] (13, -2) node [right] {\SI{5}{\volt}};
    \draw (12, -3) to [short] (13, -3) node [right] {D13};
    % Sensor
    \draw (8.5, -4.5) rectangle (11.5, -7);
    \node at (9.5, -6.5) {\textbf{Sensor}};
    \draw (9, -4) to [short] (9, -5) node [rotate=90, left] {black};
    \draw (10, -4) to [short] (10, -5) node [rotate=90, left] {blue};
    \draw (11, -4) to [short] (11, -5) node [rotate=90, left] {red};
  \end{circuitikz}
  \caption{
    $R_1 = \SI{33}{\kilo\ohm} \pm \SI{2}{\percent}$,
    $R_2 = \SI{28}{\kilo\ohm} \pm \SI{2}{\percent}$,
    $R_3 = \SI{68}{\kilo\ohm} \pm \SI{1}{\percent}$,
    $R_4 = \SI{200}{\ohm} \pm \SI{1}{\percent}$,
  }
 \end{figure}
 \end{document}
 %%% Local Variables:
 %%% coding: utf-8
 %%% mode: latex
 %%% TeX-engine: xetex
 %%% End: