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Brightness

The brightness is measured by a sensor inside the bedroom. In the simulation this will be represented by an integer light strength. The value is determined by superposing the sunlight that falls through the blinds and the light generated by our wake-up light. It is assumed there are no other light sources in the bedroom. It is also assumed that the window is always vertical and perpendicular to the suns rays.

The intensity of the sunlight is calculated based on the date and time. It is assumed the sky is clear, and there are no obstacles above the horizon.

The light coming from the wake-up light is regulated by the controller, giving an output strength, as a fraction of the full output strength( 250 lx ^[1]). These two values are then added to give the input brightness.

Temperature

The room is to be modeled as a 3x4x2.5m box filled with air, surrounded by outside air on one side and the house all other sides. This proved to be more difficult than thought, therefor we will start with a simpler, linear model for temperature change:

[math]\displaystyle{ dT = k*(T - T_\infty) }[/math]

With k a heat transition constant (estimated at k = -0.03), T the room temperature and T_∞ the temperature the room assumes when not regulated, 12°C. When the heating is on an additional term is introduced:

[math]\displaystyle{ dT_{heating} = h*(T_r - T) }[/math]

With h a convection constant (estimated at h = 0.02) and T_r the radiator temperature at 50°C

Sleep model

The Sleep Cycle App provides graphs to the user that show his measured sleep behavior during that night. Here's an example:

To model this pattern, we assumed that if the graph is split up in pieces with the peaks and valleys as cutting points, each piece will be sinusoidal with a random period and amplitude. Furthermore, we made the assumption that the period is normally distributed with mean 90 minutes or 5400 seconds (mean duration of one sleep cycle) and standard deviation 30 minutes or 1800 seconds. At first, we assumed that the amplitude is uniformly distributed, but people sleep deeper just after going to sleep and lighter just before waking up, so we had to come up with our own probability distribution. We decided to use the following probability density function:

[math]\displaystyle{ f(x) = rc \left( x - \frac{1}{2} \right) + 1 \qquad 0 \le x \le 1 \quad \and \quad -2 \le rc \le 2 }[/math]

[math]\displaystyle{ P(0 \le X \le x) = \int\limits_{0}^{x} f(x)dx = \frac{1}{2} rc \left( x^2 + \left( \frac{2}{rc} - 1 \right) x \right) }[/math]

So X is a fraction and the probability of X = x depends on the coefficient rc. How closer rc is to 2, how closer E[X] is to 1 and how closer rc is to -2, how closer E[X] is to 0. To get a random value for x, the second function needs to be rewritten, which gives:

[math]\displaystyle{ x = \frac{1}{2} - \frac{1}{rc} \pm \sqrt{ \frac{2}{rc} P(0 \le X \le x) + \frac{1}{rc^2} - \frac{1}{rc} + \frac{1}{4} } }[/math]

0 ≤ x ≤ 1, so for positive rc the ± becomes a + and for negative rc a -. If rc = 0, then this is a uniform distribution. If a value for P(0 ≤ X ≤ x) is taken from a uniform distribution with range [0,1], then a random value for x can be calculated. To model de transition from generally deep sleep to light sleep, the value of rc must decrease from 2 to -2 over time. For this we used the following function:

[math]\displaystyle{ rc = \frac{4}{1 + e^{\frac{t - 2,5T_{gem}}{20000}}} - 2 }[/math]

t is the time elapsed since going to bed and is represented by the number of ticks and Tgem is the mean duration of one sleep cycle and is in this case 90 minutes. A person needs an average of five complete sleep cycles for a good night's rest, so the point of inflection is 2.5*Tgem.

Script

globals [y
         Tgem
         start
         T
         p
         rc
         x
         R
         time
         stage
         test]

to Setup
  clear-all
  set y 100
  set Tgem (90 * 60)
  reset-ticks
end

to Go
  foreach [1 2] [
    set start y
    set T -1
    while [T < 0] [set T (random-normal Tgem 1800)]
    set p (random-float 1.0)
    set rc (4 / (1 + exp((ticks - (2.5 * Tgem)) / 20000)) - 2)
    ifelse rc > 0
      [set x (0.5 - (1 / rc) + sqrt((2.0 / rc) * p + (rc ^ -2) - (rc ^ -1) + 0.25))]
      [set x (0.5 - (1 / rc) - sqrt((2.0 / rc) * p + (rc ^ -2) - (rc ^ -1) + 0.25))]
    ifelse ? = 1
      [set R (x * start / 2)]
      [set R ((x - 1) * (100 - start) / 2)]
    set time (n-values (T / 2) [?])
    foreach time [
      set y (R * (cos (360 * ? / T)) + start - R)
      set stage ((y - (y mod 25)) / 25 - 3)
      set test (1 / (1 + exp(ticks)))
      tick
    ]
  ]
end

Result

Running the script gives these two graphs:

The first graph shows how deep you sleep on a percentage scale and the second graph translates that to the sleep stage you're in. Stage 0 means being awake and corresponds with 100%-75% on the first graph. Afterwards come stages -1, -2 and -3 which correspond with 75%-50%, 50%-25% and 25%-0% respectively. They are actually stages 1, 2 and 3, the three stages of the sleep cycle. Stage 1 can also correspond with REM sleep, because they both behave the same based on the sound you make during those stages.

User Settings

Gathering Real-Time Data

Gathering Real-Time data is rather easy using the Arduino. When connected with a computer through USB, an Arduino can print values directly to a Serial Monitor. This Serial Monitor contains the information you want, and this information can be copied into a .txt-file. There is also an external tool for Microsoft Excel, to automatically gather data from the Serial Monitor. This tool is called PLX-DAQ, and prints the Serial data directly into an Excel sheet.

The Arduino needs some code to measure the input of the sound sensor, and print the values to the Serial Monitor. A preview of this code can be seen below. This code also includes peak detection.

 const int inputPin = A0;                                // Input from the sensor
 
 int timer = 0;
 int oldValueTimer;                                      // Integer to remember old value for printing, if that turns out to be a peak
 const int maxArraySize = 100;                           // Max array size i.e. how many peaks are stored. This reduces memory needed
 int peakValues[maxArraySize];                           // Array to store the peak values
 int timeArray[maxArraySize];                            // Array to store the time the peak value is reached
 int arrayCounter = 0;                                   // Place in array to not store values that are exceeded in the next iteration
 int measurement;                                        // Sensor value
 int counter = 5;                                        // Number of averages taken. Average is taken to filter out small noise 
 int currentValue = 0;                                   // Current value
 int oldValue = 0;                                       // Previous value
 bool printPeaks = false;                                // Testing feature; if true, it will print the peak values, otherwise, it will just print the measured values
 bool oldPlus = false;                                   // Boolean to save if graph is increasing or decreasing 
                                                         //                             true          false

void setup() {
 Serial.begin(9600);                                     // Set up output window
 Serial.println("CLEARDATA");                            // Initialization of the Excel Table
 Serial.println("LABEL,Time,Peak Value");                // Names of the rows, LABEL is for the PLX-DAQ
 
 pinMode(A0, INPUT);                                     // Sensor input pin
}

void loop() {
  for (int i = 0; i <= counter; i++){                    // Loop to take average value
    delay(1000);                                         // Progress a second
    timer++;
    measurement = analogRead(inputPin);
    
    if (printPeaks == false){                            // Prints out the measurements to the Serial monitor
      Serial.print(timer);
      Serial.print(",");
      Serial.println(measurement);
    }
                        
    currentValue = currentValue + measurement;           
  }
    currentValue = currentValue / counter;               // currentValue is now the average

    if (currentValue < oldValue && oldPlus == true){     // If the graph is just behind the peak (function is decreasing, but the last measurement was increasing)
      oldPlus = false;
      if (printPeaks == true){
        Serial.print(oldValueTimer);
        Serial.print(",");
        Serial.println(oldValue);
      }
      arrayCounter++;
    }
    if (currentValue > oldValue){                        // If the value is higher than last time, store it in the array. Overwrites the last value if function is still increasing
      oldPlus = true;
      peakValues[arrayCounter] = currentValue;
      timeArray[arrayCounter] = timer;
    }
    oldValue = currentValue;                             // Update old value and reset the current value for the next loop
    oldValueTimer = timer;                                   
    currentValue = 0;
} 

References