My project was concerned with finding the relation between light intensity and electromagnetic activity at six different locations on Vassar College’s campus. The level of light intensity was found by use of a photo sensor. Electromagnetic wave levels were obtained by use of a RF Meter. These two variables were then analyzed at each respective location in order to ascertain the correlation between the two variables. This was done by calculating the coefficient of determination, or R squared value.
The coefficient of determination for the data was found to be 0.16. This means that while there is a positive correlation, it is a very weak correlation which is not statistically significant. This means that given the level of light intensity, it is unlikely that a person would be able to predict the level of electromagnetic activity and vice-versa.
Results vs Prediction
The results were contrary to my prediction. I predicted that light intensity and electromagnetic activity would have a significant correlation due to the fact that light is an electromagnetic wave itself, and therefore, hypothetically, more light would result in more electromagnetic waves. However, this experiment made it apparent that electromagnetic waves other than light have enough bearing on the total level of electromagnetic activity to result in there being no significant correlation between the two variables.
In carrying out this experiment I learned that there was an apparatus that could measure the electromagnetic wave activity passing through the air. I did not know that such a device existed. I am also very surprised that a device with this capability is inexpensive enough where an institution can own a large supply of them for students. I also learned that everything that exists in the universe has both an electric current and a magnetic field. Furthermore, I learned that the reason all matter has both an electric current and a magnetic field is due to the movement of electrons around an atom’s nucleus.
Relation with Current Technology
This experiment relates with current technology in a couple of ways. First, the RF meter is interesting in that it can be used to measure the electromagnetic waves of the Wi-Fi or Bluetooth coming off of phones and computers. This can be helpful in showing the amount of data necessitated by different applications. The other way this project relates is that there is a lot of concern by people that the waves given off by technology might be harmful to human health. However, the vast majority of scientists espouse the consensus that these waves are harmless.
What I’d Do Differently
If I were to redo this project, one thing I would do differently is utilize multiple RF meters to accrue data on electromagnetic wave levels. I would then take the average of these several readings to get the level for a location. The reason I would opt to do this is that the RF meter fluctuated greatly when obtaining a reading, which made me question its accuracy. Ideally, I would like to use RF meters manufactured by different companies so as to see if the different manufacturers’ devices fluctuate less than those possessed by Vassar’s Physics Department.
If The Project Continued an Additional 6 Weeks
If this project were extended for six additional weeks, there are a couple things I would do. First, I would add additional locations from which I would obtain data. I would do this so as to see if the correlation between light intensity and electromagnetic waves was stronger in locations other than those from which I obtained my measurements. Also, I would take measurements at all of my chosen locations at three different times between dusk and dawn. I would do this in order to see if the correlation between the two variables is weaker or stronger at different times of the night, when more or less people are awake and using electronic devices.