Notes on Different Types of "Norths"

Stefan Bozic                                         Comparing and Contrasting the "Norths"                                              Feb 23, 2013.

While researching the four types of Norths (True, Geographic, Magnetic, and Physical), I noticed that several similarities and differences exist between the four. I found out that Magnetic North holds a whole different set of properties that does not really relate to the other Norths, whereas True North and Geographic North are essentially the same. Lastly, I used the component of common sense to describe the properties of Physical North.

Geographical North and True North: The location of the poles for Geographic North is constant, meaning that it is not affected by the Earth's magnetic field. In terms of the actual direction, it is based upon the most northern point on the Earth's surface which is located at 90 degrees north of any point on the equator through which the Earth's rotational axis meets the surface of the Earth.  Due to the fact that all lines of longitude converge at this point and the fact that the Earth's axis connects both the North and South poles (line in which the earth rotates around it), Geographic North is also commonly known as True North. In addition, Geographical/True North are composed of lines of longitude and latitude which begin and end at each of the Earth's poles, and showcases North and South directions. Another trait that these two poles share are when one stands at the North Pole, all points are South of that person since East and West have no bearings. In addition, lines of longitude have established that since these lines converge at the  North Pole, Coordinated Universal Time (UTC) can be used to determine the time around the world. Lastly, this principle of the lines of longitude converging at the North Pole, also explains why the North Pole  (in Geographic and True North terms) has six months of daylight and six months of darkness. An example of the usage of these "norths" is on maps published by the Armed Forces, in which True North and Geographic is represented as five-pointed star. These "norths" can also be found on TTC Maps, or other regular hiking maps.

Magnetic North: In literal terms, Magnetic North tends to shift and move, and refers solely to the pole of the Earth's magnetic field. On the other hand, it's poles are affected by the magnetic field which is made up of a molten metallic core (composed mainly of iron). This magnetic field that causes the poles to move is created by convection and the constant rotation of the Earth combined with the core of iron.  Due to the fact that iron is magnetic (as it's inner electron shells are unstable), this proves the fact that the the location of magnetic north refers to the magnetic field. Therefore, the Magnetic North is determined by the Magnetic Field. Magnetic North is commonly used alongside compasses, as Magnetic North is located where the North end of a compass is pointing to. This means that if one were to stand on the magnetic north pole, the compass would point downward. This happens because since the same ends of magnets repulse each other, the magnetic south pole is technically the Earth's Geographic North Pole. In terms of reality,  an example of the usage for the principle of Magnetic North is a compass, which shows that  the exact direction of Magnetic North varies  time to time, because magnetic drift causes the poles to move every year. And of course, the fluid in the iron acts like a magnet, creating a weak magnetic field, making the point of "magnetic north" shift constantly. This is why 100,000 dead fish washed up on the shores of the Arkansas River last year, as the Magnetic North pole moved. 

Physical North: Due to the fact that physical is defined as "of or pertaining to the body", Physical North then refers to the North in one's perspective. This may refer to the direction you are facing or the direction in which you are walking.  For example: If one was walking to the mall, the direction in which they are walking in would be referred to as "Physical North". 

Connections: If you combine both the principles of Geographic/True North and Magnetic North, it can be seen that a relationship exists between the two since the Earth's magnet is not aligned with the geographic poles. A difference exists between these two principles, known as magnetic declination which is calculated by the angle between Magnetic North and True/Geographic North when both values are shown on a map. In addition, magnetic declination depends on the place as the value would be different in Los Angeles (12 degrees East of North) and Australia (20 degrees East of North).  For example: If a cruiser were taking a trip from Maine (20 degrees West of North) to Florida to Texas (10 degrees east), the journey would have a True/Geographic North error of 30 degrees if not adjusted for changing declination. This would result in an error for navigation. Another example would be the life of a hiker. Since maps are aligned using True/Geographic North, hikers would have to make adjustments when navigating with a compass. 

APA Citation:

Rosenberg, M. (2010, May 05). About.com. Retrieved  February 23, 2013, from

    http://geography.about.com/od/learnabouttheearth/a/northpole.html

Rosenburg, M. (2011). About.com. Retrieved February 23, 2013, from    

    http://geography.about.com/od/learnabouttheearth/a/northpole_2.htm

(2003). Retrieved February 23, 2013, from http://www.wisegeek.com/what-is-the-difference-between-the- 

    north-pole-and-magnetic-north-pole.htm

Notes on Current Electricity

Stefan Bozic                                                                   The Energy Ball Report                                                  February 3, 2013.

Differences between Parallel and Series Circuits:

                Series and Parallel circuits are two very common types of circuits with distinct properties. In a series circuit, only one path and direction exists for the current to flow through. In other words, there is only one path from the source through all of the loads and back to the source. This means that the current must flow through all of the loads in the circuit, since all the loads are connected. When paths are disconnected in a series circuit (either by detaching a wire or turning off the source), the electric current itself discontinues, resulting in a power outage and failure for the electrical device. A common example includes a string of old Christmas lights which composes of only one path for the current to flow. Breaking or opening the circuit causes the lights to stop operating because a closed path is no longer met. This is why it is very hard to identify the problem because there are several locations in which the bulb can burn out. All in all, if any of the loads or bulbs are removed, the whole circuit stops operating. In a parallel circuit, it contains multiple paths (parallel) for currents to move along and pass through, meaning that charges can move through any of the several paths found in the circuit. Due to the fact that the function of one device in the circuit does not affect the functions of the other devices in the circuit, this means that a damaged device or switch will not affect the remaining devices. The reasoning behind this is due to the fact that several parallel paths and branches are found in the circuit. This is why parallel circuits are so convenient in household electric wiring as turning off the power for the computer won't affect the power for the lights or the TV. Another reason for their differences is that both circuits calculate current and voltage differently. For example: In a series circuit, the voltage must equal the sum of the voltages from all the resistors, but in a parallel circuit the voltage remains the same for each resistor. For current, the current in a series circuit remains the same due to the fact that there is only path for the flow of electrons but for a parallel circuit, since there are multiple points the current entering these points must equal to the current exiting them.

The Function of the Energy Ball:

                A big reason as to why the energy ball does not work on some individuals has a lot to do with conductivity. Generally speaking, the human body isn't a great conductor due to the fact that is composed of several covalent bounds that according to their properties, are not great conductors of electricity. However, the human body contains dissolved ions in the form of dissolved salt (NaCl), which becomes a good conductor when dissolved in water, due to its present ionic bonds. Due to these properties, the body can act as a form of wire, ensuring that the circuit works between the body and ball (when both metal contacts are touched).   Another reason why a conductor doesn't work is the individual may simply be wearing an insulator. For example: If an individual is wearing gloves, that means that electrons will not be able to pass through, thus not completing the circuit.

Self-Reflection:

                Throughout this learning experience, I've learned many things about myself in terms of work efficiency and collaboration. Basically, I learned that I am more suited towards working independently rather than in a group, due to the fact that working in a group usually leads to several distractions and less work being done. With less focus, this obviously affects goal setting to improve work, as less tasks are completed. In addition when working in a group, there is usually a person who takes the leadership role and leads  the group to the completion of the task. However due to the fact that I am an independent person I was able to discover that I lack collaboration skills, which are needed in daily life (e.g. projects,  jobs in the future). Therefore, I should improve these valuable skills so that I can tackle all tasks with both myself and peers. 

APA Referencing:

Difference between similar terms and objects. (2007, 10 February). Retrieved February 3, 2013,  from

     http://www.differencebetween.net/science/difference-between-series-and-parallel-circuits/

EPA. (2012). Retrieved February 3, 2013,  from Environmental Protection Agency website:

     http://water.epa.gov/type/rsl/monitoring/vms59.cfm

Michael, S. (2012, May 29). allaboutcircuits.com. Retrieved February 3, 2013,  from 

     http://www.allaboutcircuits.com/vol_1/chpt_1/2.html