STATISTICS IN ASSESSMENT OF LEARNING

 

STATISTICS IN ASSESSMENT OF LEARNING

Meaning of Statistics:

1.       Statistics is a branch of mathematics, which deals with the collection, analysis and interpretation of data obtained by conducting a survey or an experimental study.

2.       Statistics can be defined as the collection, presentation and interpretation of numerical data. ----- Croxton & crowed.

Need and Importance of Statistics in Education

    Statistics, in general, renders valuable services in the following dimensions:-

(a)    In the collection, evidences or facts (numerical or otherwise).

(b)    In the classification organization and summarization of numerical facts.

(c)     In drawing general conclusions and inferences or making predictions on the basis of particular facts and evidences.

        On account of the above mentioned services statistics is now regarded as an indispensable instrument in the field of Education, especially where any sort of measurement or evaluation is involved. Its need in Education can be summarized as below:-

1.       In the construction and standardization of various tests and measures.

       Statistical methods helps in the construction and standardization of various tests and measures like Achievement tests in various subjects. Intelligence tests, Aptitude tests, Interest, Inventories, Attitude Scales and various other measures of personality assessment.

2.       In making proper use of the results of various tests and measures.

    Scores obtained from various tests and measures are always relative and not absolute. Hence they are meaningless in themselves. Statistical methods help in their proper presentation, comparison and interpretation. This services rendered by statistics help us:-

i)                    To know individual differences of our students,

ii)                   To render guidance to the students,

iii)                 To compare the suitability of one method or technique over the other,

iv)                 To compare the results of one system of evaluation with the other,

v)                   To compare the function and working of one institution with the other.

vi)                 To make prediction regarding the future progress of the students.

vii)               To make selection, classification and promotion of the students.

viii)              To keep various types of records and furnish Educational statistics etc.

     By the above services of statistics in Education, it can be easily concluded that it is very helpful to the teachers in the proper functioning of their various duties. It gives a definite direction to the process of teaching and learning and helps the teacher to realise the broader aims and objectives of education. By its increasing popularity in psychological as well as educational researches, it is now going to be most indispensable to every teacher. Its knowledge not only helps a teacher in acquainting with the new innovations and researches in the field of education but also prepares him to become an active participant in introducing as well as bringing changes in the field of Education.

Uses of Statistics in Education

1.       It helps in collecting data either numerically or otherwise.

2.       It also helps in classification, organization and summarization.

3.       It also helps us in drawing general conclusion and measurement.

4.       Statistics also helps in task of evaluation and measurement.

5.       It helps in the construction and standardization of test as well as using them properly.

6.       It helps the teacher to know the individual differences of the students, comparing the suitability of one method or technique with another, making predictions for the future etc.

THE FREQUENCY DISTRIBUTION

     Frequency distribution may be considered as a method of presenting a collection of groups of scores in such a way as to show the frequency in each group of scores or class.

Steps in preparation of frequency distribution:

1.       Finding the Range of the series. i.e., R=H-L

2.       Determining the class interval. i.e.,  i = Range/class desired.

3.       Writing the contexts of the frequency distribution.

i)                    Classes of the scores ii) Tallying the scores in to proper classes. iii) Checking the table. 

4.       Preparing the table of frequency distribution.

Class interval (C.I)	Tallies	Frequency  (f)

Problems:

1)    Construct the frequency distribution table for the following data/scores:

72, 75, 77, 67, 81, 68, 65, 86, 73, 67, 69, 82,

76, 76, 70, 83, 71, 63, 72, 72, 61, 84, 64, 67,

Ans: R=H-L

         R =86-61=25

         R=25

        i = Range/class desired.

         = 25/5 =5

        i =5

 

Class interval (C.I)	Tallies	Frequency (f)
60- 64	III	3
65 – 69	IIII  I	6
70 – 74	IIII  I	6
75 – 79	IIII	4
80 – 84	IIII	4
85 - 89	I	1

 

                                                                                                N=  ∕24

 

 

 

2)    Construct the frequency distribution table for the following data/scores:

Note: In the above example, the total no. of scores=50, 
Highest score=68
Lowest score=21
\Range=68-21=47
Hence, here 10 classes are sufficient. 
\i=47¸10=4.7 (approx.5)

3)      Construct the frequency distribution table for the following data/scores:

31, 20, 14, 26, 36, 49, 28, 27, 25, 32, 43, 15,

40, 32, 28, 20, 24, 27, 27, 23, 31, 27, 32, 36,

24, 27, 32, 26, 45, 22, 12, 30, 29, 16, 50, 10,

25, 16, 24, 34, 42, 26, 20, 44, 18, 28, 26, 41,

35, 28, 26, 22, 33, 32, 26, 21, 25, 38, 44, 18,

4)      18, 13, 09, 24, 13, 16, 12, 10, 11, 22,

12, 21, 04, 09, 03, 14, 13, 17, 16, 18,

13, 09, 07, 04, 15

Advantages of Frequency Distribution

1.       It makes data easier to interpret.

2.       It gives one a fairly clear picture of how students have performed. For example, the largest group has got the scores between 25 and 29, while the majority of the group have scored between 20 and 34.

3.       If Lakshmi’s score is 46, we can estimate her relative position in the group and can express our qualitative judgement about her position.

4.       It increases the clarity of the form of the distribution of scores.

Limitations of Frequency Distribution

1.       Some information is lost. For example, the scores of 15, 16, 16, 18 and 18 have all been put in the interval 15 – 19 (14.5 – 19.5). Again one cannot say which exact measures have been included, say, in the interval 30-34.

2.       From the table, one does not know the score of the 25^th student in the series.

3.       For further calculations, one has to assume that either (i) the scores are uniformly distributed over the theoretical limits of the interval, or (ii) all scores fall on the midpoint of the interval. The degree to which such assumptions affect the accuracy of the graphs and statistics computed from a class interval depends upon the size and number of class intervals and the total frequency of the scores.

Limits of Class Intervals

    There are various ways in which the limits of class intervals are expressed are given below,

         Method – A                                      Method – B                                  Method – C

        40 – 50                                                   40 – 49                                         39.5 – 49.5

        50 – 60                                                   50 - 59                                         49.5 – 59.5

        60 – 70                                                   60 – 69                                        59.5 – 69.5

       ............                                                        …………                                             …………….

GRAPHIC REPRESENTATION OF DATA

 

   GRAPH: The diagrammatical representation of numerical data is called Graph.

Data may also be graphed in various ways. Viz. the histogram, the frequency polygon, etc.

 

Advantages of Graphic Representation

1.       It helps greatly in enabling us to understand the data of frequency distributions.

2.       It helps us in analyzing numerical data.

3.       It helps us in comparing different frequency distributions to each other.

4.       It catches the eyes and holds the attention which other statistical evidences fail to attract.

5.       It helps us to dilute the abstractness of ideas by translating numerical facts into a more concrete and understandable form. It permits easy visualization.

 

 

The Histogram

  It is the graph in which the frequencies are represented by bars or columns. It appears as a series of bar graphs placed one next to the other in a vertical array.

Example: Construct the Histogram from the following distribution table

 

Class Interval (C.I)	Frequency (f)
10- 14	3
15 - 19	5
20 - 24	9
25- 29	18
30 - 34	11
35 -39	5
40 - 44	6
45- 49	2
50 - 54	1

                                                                                  N =        60

                               ___________________________________________

   Steps:

1.       Mark the class interval along x=axis.

2.       Mark the frequency along y-axis.

3.       Heights of the rectangle should be proportional to the frequency.

4.       Construct adjacent rectangle of the same width.

Properties of the histogram:

1.      Frequencies are along the vertical axis and the scores (C.I) are along the horizontal axis.

2.      One assumes that the scores are evenly distributed within the class interval, thus giving us rectangular bars.

3.      The frequencies within each interval of a histogram are represented by a rectangle, the size of the interval being the base and the frequency of that interval the height.

4.      The area of each rectangle in a histogram corresponds to the frequency within a given interval. While the total area of a histogram corresponds to the total frequency (N) of the distribution.

Advantages:

1.       It is simple and easily made.

2.       All the five advantages of the graphic representation are applicable here.

Limitations:

1.       It is difficult to superimpose more than one histogram on the same graph.

2.       Comparisons of several frequency distributions cannot readily be made via histograms. Frequency polygons are much better suited for that purpose.

3.       The assumption that the scores are evenly distributed within the C.I. produces a larger error when N is small than when N is large.

4.       It cannot be smoothed.

 

The frequency Polygon

     A polygon is a many angled close figure. The frequency polygon is a graphic representation of frequency distribution in which the mid points of the C.I are plotted against the frequencies.

Example: Construct the Frequency polygon from the following frequency distribution table.

 

Class Interval (C.I)	Frequency (f)	Mid-point       (x)
10- 14	3	12
15 - 19	5	17
20 - 24	9	22
25- 29	18	27
30 - 34	11	32
35 -39	5	37
40 - 44	6	42
45- 49	2	47
50 - 54	1	52

                                                                                  N =        60

Properties of the frequency polygon

1.      Frequencies are along that vertical axis and the scores (representing the midpoints of C.I) are along the horizontal axis.

2.      One assumes that all scores within a class interval fall at the midpoint of that interval.

3.      The midpoint of the class intervals just above and below the highest and lowest intervals that contain the actual scores are also marked on the horizontal axis and given a frequency of zero. This is done to close the figure.

Advantages

1.       It is simple and easily made.

2.       It is possible to superimpose more than one frequency polygon on the same graph by using coloured lines, broken lines, dotted lines, etc.

3.       Comparisons of several frequency distributions can readily be made via frequency polygons.

4.       All the advantages of the graphic representations are applicable here.

5.       It can be smoothed.

Limitations

1.       The part of the area lying above any given interval cannot be taken as, proportional to the frequency of that C.I owing to irregularities in the frequency surface.

2.       The assumption that all the scores within a C.I fall at the midpoint of the interval produces a larger error when N is large than when N is small.

3.       It is less precise than the histogram in that it does not represent accurately, i.e.  in terms of area, the frequency upon each interval.