Write an essay on Statistical Analysis.
In this assignment, the “number of admissions” to the movies in Australia was surveyed from the year 1994 to 2014. Other factors were also surveyed in this assignment. The data for the variables of “Screens”, “Theatres”, “Films Screened”, “Real Ticket Price” and “Capacity” were also collected from the year 1994 to 2014 (Bickel and Lehmann 2012). These data were used in this assignment for the analysis.
Statistical analysis would be done on this data set. “Descriptive statistics”, “inferential statistics” and concepts of “linear regression methods” would be given in this assignment based on these data (Vogt and Barta 2013). Graphs and charts would also represent the data and provide conclusion about the data and their relations.
|
Screens |
|
|
Mean |
1213.52381 |
|
Standard Error |
103.6609083 |
|
Median |
1028 |
|
Mode |
#N/A |
|
Standard Deviation |
475.0339587 |
|
Sample Variance |
225657.2619 |
|
Kurtosis |
-1.569616636 |
|
Skewness |
0.410014464 |
|
Range |
1264 |
|
Minimum |
645 |
|
Maximum |
1909 |
|
Sum |
25484 |
|
Count |
21 |
|
Largest(1) |
1909 |
|
Smallest(1) |
645 |
|
Confidence Level (95.0%) |
216.2328649 |
|
Admissions (millions) |
|
|
Mean |
61.82380952 |
|
Standard Error |
5.151804606 |
|
Median |
68.1 |
|
Mode |
92.5 |
|
Standard Deviation |
23.60853457 |
|
Sample Variance |
557.3629048 |
|
Kurtosis |
-1.666346431 |
|
Skewness |
-0.055528974 |
|
Range |
63.6 |
|
Minimum |
28.9 |
|
Maximum |
92.5 |
|
Sum |
1298.3 |
|
Count |
21 |
|
Largest(1) |
92.5 |
|
Smallest(1) |
28.9 |
|
Confidence Level (95.0%) |
10.74647607 |
|
Theatres |
|
|
Mean |
545.0952381 |
|
Standard Error |
9.45840638 |
|
Median |
547 |
|
Mode |
520 |
|
Standard Deviation |
43.34386319 |
|
Sample Variance |
1878.690476 |
|
Kurtosis |
8.375821966 |
|
Skewness |
2.445313468 |
|
Range |
201 |
|
Minimum |
501 |
|
Maximum |
702 |
|
Sum |
11447 |
|
Count |
21 |
|
Largest(1) |
702 |
|
Smallest(1) |
501 |
|
Confidence Level (95.0%) |
19.72988992 |
|
Films Screened |
|
|
Mean |
257.3809524 |
|
Standard Error |
5.769573802 |
|
Median |
255 |
|
Mode |
259 |
|
Standard Deviation |
26.43950868 |
|
Sample Variance |
699.047619 |
|
Kurtosis |
1.256326286 |
|
Skewness |
-0.057083837 |
|
Range |
124 |
|
Minimum |
194 |
|
Maximum |
318 |
|
Sum |
5405 |
|
Count |
21 |
|
Largest(1) |
318 |
|
Smallest(1) |
194 |
|
Confidence Level (95.0%) |
12.03512002 |
|
Real Ticket Price |
|
|
Mean |
19.77952381 |
|
Standard Error |
0.091997609 |
|
Median |
19.66 |
|
Mode |
#N/A |
|
Standard Deviation |
0.421586008 |
|
Sample Variance |
0.177734762 |
|
Kurtosis |
0.085043332 |
|
Skewness |
0.91600328 |
|
Range |
1.51 |
|
Minimum |
19.25 |
|
Maximum |
20.76 |
|
Sum |
415.37 |
|
Count |
21 |
|
Largest(1) |
20.76 |
|
Smallest(1) |
19.25 |
|
Confidence Level (95.0%) |
0.191903649 |
|
Capacity (‘000s) |
|
|
Mean |
362.8095238 |
|
Standard Error |
15.57082422 |
|
Median |
332 |
|
Mode |
295 |
|
Standard Deviation |
71.35448062 |
|
Sample Variance |
5091.461905 |
|
Kurtosis |
-1.582996919 |
|
Skewness |
0.44357307 |
|
Range |
186 |
|
Minimum |
285 |
|
Maximum |
471 |
|
Sum |
7619 |
|
Count |
21 |
|
Largest(1) |
471 |
|
Smallest(1) |
285 |
|
Confidence Level (95.0%) |
32.48017007 |
Considering the variable “admission (millions)”, the central tendency the variable, i.e. the mean is 61.8238. The median of the variable is 68.1. This is the middle value of the “admission (millions)” is 68.1. The modal value of the variable was 92.5 (Plonsky 2015). This is the maximum frequency for the number of people who were admitted for the movie. The variability of the variable; i.e. the standard deviation is 23.6085. This depicts that the variable had a moderate amount of variability in the “admission (millions)” over the years (Vogt and Barta 2013). The shape of the distribution is “platykurtic” and the distribution is negatively skewed.
The mean of the variable “screens” was found to be 1213.5238. The median of the variable was 1028 and there was no mode for this variable. The standard deviation of the variable was 475.0339 (Thiem 2014). This depicts that there was moderate variation in the number of screens available in Australia for screening of movies. The shape of the distribution id platykurtic and it is positively skewed.
The average value of “theatres” was found to be 545.095. The median of the variable is 547 and its mode is 520. The standard deviation was 43.34. There was a low deviation in the number of theatres open in Australia during 1994 to 2014 (Campbell and Knapp 2013). The shape of the distribution is leptokurtic and the distribution is positively skewed.
The average value of the variable “films screened” was found to be 257.38. The median value was 255 and the modal value was 259 (Ang and Van 2015). The standard deviation was found to be 36.439. This variable had a low deviation of the number of theatres opened in these years. The shape of the distribution is leptokurtic and it is negatively skewed.
The mean of the variable “real ticket price” is 19.779 and its median is 19.66. the standard deviation of the variable is 0.42 (Kleinbaum et al. 2013). This is a very low standard deviation and the price of the tickets fluctuated little during the period of 1994 to 2014. The shape of the distribution is leptokurtic and the distribution is positively skewed.
The average value of the variable “capacity” was found to be 362.8095. The median was 332 and the mode was 295. The standard deviation of the variable was 71.3544. This depicts that there was moderate variation among the daily capacity of the customers over the years. The shape of the distribution is platykurtic and the distribution is positively skewed.
Graph displaying the distribution of “admission”
Box-and-whisker plot for the distribution of the “real ticket price” is given below
The likelihood that the admission is greater than 70 million when the real price of the ticket is more than $20 is given by P(X > Z) = 1 – P( X< Z) = 1- 0.613 = 0.387 (Campbell and Knapp 2013).
The “admissions” are statistically independent of “price”. This is because the value of the chi square test was found to be zero. The contingency table is as follows:
|
Sum of probability of admission |
Column Labels |
||||||||||||||||||||
|
Row Labels |
28.9 |
29.7 |
30.8 |
35.5 |
37.4 |
39 |
43 |
46.9 |
47.2 |
55.5 |
68.1 |
69.9 |
73.9 |
76 |
80 |
82.2 |
88 |
89.8 |
91.5 |
92.5 |
Grand Total |
|
19.25-19.35 |
0.036 |
0.071 |
0.107 |
||||||||||||||||||
|
19.35-19.45 |
0.030 |
0.036 |
0.043 |
0.063 |
0.172 |
||||||||||||||||
|
19.45-19.55 |
0.068 |
0.071 |
0.139 |
||||||||||||||||||
|
19.55-19.65 |
0.024 |
0.069 |
0.093 |
||||||||||||||||||
|
19.65-19.75 |
0.022 |
0.029 |
0.051 |
||||||||||||||||||
|
19.75-19.85 |
0.023 |
0.062 |
0.084 |
||||||||||||||||||
|
19.85-19.95 |
0.027 |
0.027 |
|||||||||||||||||||
|
19.95-20.05 |
0.070 |
0.070 |
|||||||||||||||||||
|
20.05-20.15 |
0.059 |
0.059 |
|||||||||||||||||||
|
20.15-20.25 |
0.057 |
0.057 |
|||||||||||||||||||
|
20.35-20.45 |
0.033 |
0.033 |
|||||||||||||||||||
|
20.45-20.55 |
0.054 |
0.054 |
|||||||||||||||||||
|
20.75-20.85 |
0.052 |
0.052 |
|||||||||||||||||||
|
Grand Total |
0.022 |
0.023 |
0.024 |
0.027 |
0.029 |
0.030 |
0.033 |
0.036 |
0.036 |
0.043 |
0.052 |
0.054 |
0.057 |
0.059 |
0.062 |
0.063 |
0.068 |
0.069 |
0.070 |
0.142 |
1 |
H0 = the admission from 2008 to 2014 did not exceed the constant amount of 84 millions in Taiwan
H1 = the admission from 2008 to 2014 had exceeded the constant amount of 84 millions in Taiwan
On testing the two variables, the p value of the one-tailed test was found to be 0.02732, which is less than the p value (Levy and Lemeshow 2013). The “null hypothesis” in this case is rejected and the admission from 2008 to 2014 had exceeded the constant amount of 84 millions in Taiwan.
H0 = there is no difference between the ticket price in 2014 and zero at 5% level of significance
H1 = there is difference between the ticket price in 2014 and zero at 5% level of significance
The p value of the regression analysis for the variable “real ticket price” had the value of 0.044, which is less than 0.05. This leads to the rejection of “null hypothesis”. Thus, there is difference between the ticket price in 2014 and zero at 5% level of significance. The slope of the variable is 5.2766, which is positive (Montgomery et al. 2015). This states that the variable effects the “admission” in a positive way. The change in price in the ticket leads to the change in the admission in the similar direction.
The value of intercept was found to be negative. This suggests that the “admission” would be negative in absence of all the factors. The slope of “Screens” was 0.0878, which was slightly positive (Draper and Smith 2014). This value aims to influence the “admission” in a positive manner, as the value is positive. The value of the slope of “Theatres” was found to be 0.04508, which is positive. This depicts that the factor had a weak positive influence of the “admission”. The slope of “Flimsy screened” was 0.001 and it is weakly negative (Csikszentmihalyi and Larson 2014). This also influences the “admission” positively and the change in value of this variable changes the value of “admission” in the same direction (Kleinbaum et al. 2013). The slope of “capacity (‘000s) has a negative slope of -0.2819. This indicates that the variable influence the “admission” in a negative way. The increase in capacity decreases the “admission”.
All the slope of the variables had the same sign as was expected. The sign of “capacity (‘000s)” was expected to be positive whereas it turned out to be negative.
The value of adjusted r square is 0.971. This indicates that 97.1% of variation is explained by only the independent variables that actually affect the dependent variable (Fox 2015).
The p value of the variables “theatres” and “film screened” are more than 5% “level of significance”. The other three variables have their p value less than 0.05. Thus, this overall model is statistically not significant as the p values of all the variables are not less than 0.05.
Scatter diagram and histogram
The variable is heteroscadastic, normal and linear.
Variables like “location of the theatre”, “facilities provided in the theatre” and “the type of movie” influence the “admission” positively. These factors would increase the value of regression coefficient and would thereby, influence the regression coefficient.
The sampling process of random sampling would not be appropriate one at the first instance. The organisation must identify all the households of native-born Australians. They could then use the process of random sampling to select the households from the identified households.
Conclusion
It was seen from the analysis that the variable “admission” is influenced by various factors like the “Screens”, “Theatres”, “Films Screened”, “Real Ticket Price” and “Capacity”. The “average”, “standard deviation” and the type of distribution of each variable vary from each other over the period from 1994 to 2014. The graphs show the distribution of each variable and the tables give an idea about the type of “admission” with the “real ticket price”. The degree of association between the variables was also analysed. Thus the analysis gave a clear picture about the variables and the effect of “admission” over the years 1994 to 2014 and the influence of the other factors on the “admission”.
References
Ang, S. and Van Dyne, L., 2015. Handbook of cultural intelligence. Routledge.
Bickel, P.J. and Lehmann, E.L., 2012. Descriptive statistics for nonparametric models I. Introduction. In Selected Works of EL Lehmann (pp. 465-471). Springer US.
Campbell, J.P. and Knapp, D.J. eds., 2013. Exploring the limits in personnel selection and classification. Psychology Press.
Csikszentmihalyi, M. and Larson, R., 2014. Validity and reliability of the experience-sampling method. In Flow and the Foundations of Positive Psychology (pp. 35-54). Springer Netherlands.
Draper, N.R. and Smith, H., 2014. Applied regression analysis. John Wiley & Sons.
Fox, J., 2015. Applied regression analysis and generalized linear models. Sage Publications
Kleinbaum, D., Kupper, L., Nizam, A. and Rosenberg, E., 2013. Applied regression analysis and other multivariable methods. Nelson Education.
Levy, P.S. and Lemeshow, S., 2013. Sampling of populations: methods and applications. John Wiley & Sons.
Montgomery, D.C., Peck, E.A. and Vining, G.G., 2015. Introduction to linear regression analysis. John Wiley & Sons.
Plonsky, L., 2015. Statistical power, p values, descriptive statistics, and effect sizes: A” back-to-basics” approach to advancing quantitative methods in L2 research.
Thiem, A., 2014. Membership function sensitivity of descriptive statistics in fuzzy-set relations. International Journal of Social Research Methodology,17(6), pp.625-642.
Vogt, A. and Barta, J., 2013. The making of tests for index numbers: Mathematical methods of descriptive statistics. Springer Science & Business Media.
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