Effect of Self Regulated Learning Strategies on Engineering Students Thanikachalam.V., B.E., M.Tech., Ph.D., M.S.,FIE., FIGS., FFIUCEE FMR FULBRIGHT SENIOR RESEARCHER, and Former Professor and HOD., CIA., NITTTR ,Chennai
Problem of the First Year Students
Most of the first year students displayed maximum academic achievement at the time of entry in to the engineering program but their performance deuterated after joining.
Even very high achievers failed in many basic and core courses.
The problem is due to self-regulation which relates to the use of processes such as thinking, taking action, behaving and engaging in purposeful activities.
The engineering students are self-directed, autonomous, and independent.
They tend to learn what they believe that what they need to know.
These issues are to be investigated and solutions have to be identified.
Objectives
To identify the possible reasons for large percentage of failures of engineering students in the basic and core courses though they have achieved very well in their higher secondary education.
To assess the students’ learning process, self-system, learning and belief, perceived value of learning tasks and metacognitive system.
To suggest guidelines to the faculties on students’ self-system, counselling the students on the utilities of core and basic courses in engineering and use the principles of andragogy in the instructional design.
To create an academic environment which will help the students pursue the basic and core courses productively
Research Methodology
Comparison of achievement between the standard group and experiment group.
A set of six colleges have been selected and 30 faculty members have been selected.
They have been trained in Andragogy, cognitive system, metacognitive system, selfsystem, students learning process, learned helplessness system, at risk students, and perceived value of tasks.
The faculty members have been trained to identify the learning difficulties of their students and the performance of the students on the basic and the core courses in the semester examinations.
They have been guided to redesign the course outcomes and the instructional methods.
The needs of various courses, course objectives, their utility in engineering and the outcome have been discussed.
Implementation
The revised and improved courses included many field specific courses.
This created purposeful learning environment.
They communicated the value of learning the basic and core courses and their impact on engineering problem analysis, design, and prototype development.
This helped the students to focus on the cognitive system, learning process, intrinsic motivation, and improved performance.
The outcomes of the methodology has been assessed through the results in the semester examination.
The results are presented in Table-1
Outcome in Basic and Core Courses (Table-.1.1)
College
Standard Group (Basic) Class Average Mark in %
Test Group (Basic) Class Average Mark in %
Standard Group (Core) Class Average Mark in %
Test Group (CORE) Class Average Mark in %
C1
62.4
74.7
58.2
69.7
C2
67.3
77.1
59.3
69.8
C3
68.5
78.5
60.7
70.1
C4
59.6
69.4
58.6
67.2
C5
58.5
75.1
56.6
67.7
C6
57.4
69.3
54.4
63.7
Average
62.28
72.35
57.97
67.97
% of increase
16.17
17.37
Comparison of % Gained in the Examination in the Basic and Core Courses
Basic courses
Core courses
Chemistry
Drawing
Physics
Engineering courses
Mathematics Average pass percent increase: 16.7
Average pass percent increase: 17.37
Very significant
Very significant
Comparison of % gained in the Advanced Courses Advanced Courses Engineering Design and Drawing Average % increase: 5.99 Inference: The students have in depth motivation to excel in the analysis, design, drawing and estimation. However, when the instruction was based on andragogy, higher order cognitive system, metacognitive system, self-system, students learning process, and achievement motivation, the average percent increase is 5.99. But in the case of Basic Courses and Core Courses the increase is very significant. Hence, the students in the first semester need more focus on the utility of basic and core courses.
Outcome in the Advanced Course (Table-1.2) College
Standard Group
Test Group
C1
86.1
91.1
C2
86.3
90.8
C3
89.1
92.4
C4
88.4
92.3
C5
80.7
89.1
C6
81.6
87.2
Average
85.37
90.48
% of Gain
5.99
Conclusions
The faculty members of Basic courses (Chemistry and Physics) need to be exposed to the application of these courses in engineering materials, properties, and applications.
They may be taken around the engineering laboratories.
The faculty members in mathematics need to be exposed on the application of mathematics in the engineering analyses, design and testing.
These faculty can plan some courses in the engineering in cooperation with engineering faculty members.
All the faculty need exposure to andragogy, high order cognitive system, metacognitive system, self-system, students’ learning process, learned helplessness, at risk students, insentric motivation and achievement motivation.