The Mutual Connection between Currents and Voltages for Several Devices

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The present work studies the relationship between the electric current applied to the body and the measured voltage using an experimental approach. It is known that current and voltage are related using Ohms law for direct current, so it was expected that the different resistances of the devices used would affect the measured voltage. In addition, it was interesting to investigate the correlation between voltage and current. The main findings of this paper were that the active resistance value was different for each of the devices used  Wooden Spool, Filament Bulb, Electric Fan, Ohm Resistor. In addition, the Pearson coefficient for current and voltage showed a strong positive relationship. Thus, the study fully confirmed Ohms law.

Introduction and Background

Different physical bodies conduct electric current differentially due to their nature and structure. Current should be understood as the ordered motion of charged particles, usually electrons (Gregersen, 2020). Because substances do not conduct electric current in the same way, the term resistance should be introduced. Resistance is the ability of a substances crystal lattice to prevent or hinder the free flow of current. In other words, the stronger the active resistance of a substance, the less electric current will be able to flow through that body (CK-12, 2019). The third figure in the relationship between resistance and current is the voltage as a measurable potential difference. In theoretical terms, voltage shows the ratio of the work done by an electric field to move a charge to the numerical value of that charge. All three parameters are related by a single Ohms Law, which postulates the relationship Formula (Khawaja, 2022). The present laboratory work investigates the relationship between voltages and currents within different bodies with expectedly different resistances. Two hypotheses are tested in the work: first, there are different active resistances for the different bodies used in the present experiment. Secondly, the more current was applied to the device, the more voltage was measured.

Method

The methodological basis of the experiment was based on the use of four different devices, through which a direct current of the measured strength was passed. For each of the four devices, the voltage value was also measured with a voltmeter, the ends were connected to the body with wires. The devices used included a Wooden Spool, Filament Bulb, Electric Fan, and Ohm Resistor. Since each of the bodies was a conductor, receiving zero voltages was not expected; however, the device would have been replaced by another if this had occurred. The primary data thus included a summary table of current values (in mA) and voltages (in V) for each of the four bodies (see Table 1). The data were then used for statistical analysis, which was to test the two previously given hypotheses.

Results

A summary table of the collected data is presented at the end of the work; the histogram shown in Fig. 1 was constructed from this table. The histogram shows the values of the applied currents and measured voltages for each of the four devices. In addition, the correlation was measured for the distribution of currents and voltages to determine the strength and direction of the relationship between the variables. The Pearson correlation coefficient was calculated using MS Excel as 0.817, indicating a strong positive relationship between applied currents and measured voltages. Finally, as part of the work, the values of all resistances according to Ohms law were calculated: the results are shown in Table 2.

Histogram of Currents and Voltages for the Devices
Figure 1: Histogram of Currents and Voltages for the Devices

Discussion

The present work aimed to investigate the relationship between voltages and currents using an experiment with four different devices. An applied current of varying strength was passed through the bodies of the devices and was expressed as a change in voltage, recorded with a voltmeter. In Figure 1, it was shown that the increase in applied current was precisely related to the increase in voltage, but the rate of this increase differed for each of the devices because of the different active resistance of the conductor. In addition, the Pearson coefficient demonstrated that as the current increases, the voltage increases invariably, indicating a strong positive relationship between the two variables. Thus, the results confirm the two initial hypotheses of this experiment and provide further proof of the practical application of Ohms law.

This experiment may have several limitations. First, the experimental sample of devices was not large enough, which may have affected the statistical reliability of the results  increasing the sample size solves this problem. Second, the current and voltage values may have been measured at different temperatures, which affected the resistance of the conductor  fixing the physical environment also solves this problem. A reasonable strategy is to measure the relationship between currents and voltages for AC rather than DC in future studies.

References

CK-12. (2019). 20.8 resistance. CK-12. Web.

Gregersen, E. (2020). Electric current. Britannica.

Khawaja, F. (2022). What is Ohms law and how do you calculate resistance equations? MUO.

Tables, Charts, and Figures

Table 1: Summary Table of Primary Data

DEVICE CURRENT (mA) VOLTAGE (V)
Wooden Spool 10 0.15
Filament Bulb 360 15.5
Electric Fan 300 9
Ohm Resister 90 10

Table 2: Calculation of Resistances for Each of the Sources

DEVICE RESISTANCE  ©
Wooden Spool 0.015
Filament Bulb 0.043
Electric Fan 0.030
Ohm Resister 0.111

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