SEMESTER LEARNING PLAN
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Course Title: General Mathematics 2 (MD2)
MK code: AKM21 326
Credit Weight: 2
Group of Courts: Compulsory
Semester: 3
Prerequisite Course: No requirement
Lecturer:
Robertus Heri Soelistya Utomo, S.Si., M.Si.
Graduate Learning Outcomes (GLO)
Attitude  GLO 1(S9)  Demonstrate an attitude of responsibility for work in their field of expertise independently. 
Knowledge  GLO 2(PP3)  Mastering the basic principles of software for the analysis and identification of solid material 
General Skills  GLO 3 (KU1)  Able to apply logical, critical, systematic, and innovative thinking in the context of the development or implementation of science and technology that pays attention to and uses humanities values by their field of expertise 
GLO 4 (KU2)  Able to demonstrate independent, quality, and measurable performance.  
GLO 5 (KU5)  Able to make decisions regularly in the context of solving problems in their area of expertise, based on the results of analysis of information and data  
Special skill  GLO 6 (KK1)  Able to generate appropriate conclusions based on the results of identification, analysis, isolation, transformation, and synthesis of chemicals that have been carried out 
Course Description
Physical and chemical properties of Macroscopic Systems in Chemistry, namely a mixture (homogeneous or heterogeneous) of interacting molecules or atoms is a function of environmental parameters (number of moles, n, temperature, T, pressure, P, volume, V, intermolecular interaction distance, R), for example, the energy in the system U=f(n, T, P, V, R), and can change by changes in environmental parameters. The kinetic energy of particles in a macroscopic system is a function of temperature and particle velocity, Ek=f(n, T, c). The change in the amount of a substance with and without a reaction is a Function of Differential Equations. A chemical reaction is a differential equation of the amount of a sense for the reaction time. Physical and chemical properties of the Microscopic System of molecules, atoms, electrons in particles, and atomic nuclei are the operations of differential Hamiltonian to Function, Hψ=Eψ. So the function of the electron system in an atom can be obtained by solving a partial differential equation of order 2 or 3 dimensions which is used to describe the system. The change function is a differential equation and needs to be solved by nonanalytic or numerical integration. The function of a chemical system often has to satisfy certain conditions such as continuity, fulfilling the Probability Distribution Function as a function of energy and temperature. The change can reach a minimum or maximum point where the first derivative of the function is zero. Based on the description above, the subjects of mathematics in chemistry are
(1) Vector
(2) Determinants
(3) Application of Vectors and Determinants
(4) Correlation and Fitting Function
(5) Integration Technique 2
(6) Partial Differential Equations of Order 1 and Order 2
(7) Application of Partial Differential Equations
Week  Expected ability (SubCLO)  Study Materials/ Learning Materials  Learning methods  Student Learning Experience  Time (minutes)  Evaluation  
Criteria and Indicators  %  
12  Students can explain (C2understand) the function of mathematics and its benefits in chemistry.  Functions: Linear functions, Quadratic functions, Trigonometric functions, Exponential functions, and other functions in chemistry  Discovery learning
Cooperative learning 
Summarizing information
Asking (development, critique) search, collect and compile information to describe the Functional Benefits in chemistry. Discuss and conclude problems/tasks in groups 
FF : 2x 50 min
SS : 2 x 50 min ST : 2 x 50 min 
accuracy explains the benefits of Functions in chemistry with a minimum accuracy of 80%  15 
34  Students can compare (C2understand) the Derivatives of Functions on various types of Functions in PB1.  Function Derivatives: the meaning and benefits of negative, zero, and positive derivatives of functions at the price of a specific independent variable  Discovery learning
Cooperative learning Problem Based Learning 
listen,
write ask Discuss and conclude problems/tasks in groups 
FF : 2x 50 min
SS : 2 x 50 min ST : 2 x 50 min 
Accuracy of calculating the Derivatives of Functions in PB1.  15 
56  Students can explain (C2understand) the function and Derivatives of Functions and uses (C3apply) on Thermodynamics, Kinetics, and Structures.  Application of Functions and Function Derivatives in Thermodynamics, Kinetics, and Structures (Orbitals)  Discovery learning
Cooperative learning Problem Based Learning 
listen,
write, ask Learning by digging/looking for information (inquiry) and use that information to solve real problems. 
FF : 2x 50 min
SS : 2 x 50 min ST : 2 x 50 min 
– the accuracy of explaining the Derivative Function.
– the accuracy of explaining the problems given application to Thermodynamics, Kinetics, and Structures. 
10 
7  Students can explain (C2understand) Limits and Continuous Functions and Continuous Functions and use (C3apply) in Thermodynamics, Kinetics, and Structures.  Limits and Continuous Functions on Functions  Discovery learning
Cooperative learning Problem Based Learning 
listen,
write ask Learning by digging/looking for information (inquiry) and use that information to solve real problems. 
FF : 2x 50 min
SS : 2 x 50 min ST : 2 x 50 min 
– Accuracy of explaining Limit and Continuous Function.
– Accuracy in explaining Limits and Limit Functions and Continuous Functions. – Accuracy in explaining Limit and Continuous Function questions given 
10 
8


Midterm exam  Written exam  90  The truth and completeness of the answer to the question  50  
910  Students can explain (C2understand) Integration Techniques and use (C3apply) in Thermodynamics, Kinetics, and Structures  Integration Techniques on Functions  Discovery learning
Cooperative learning Problem Based Learning 
listen,
write ask Learning by digging/looking for information (inquiry) and use that information to solve real problems. 
FF : 2x 50 min
SS : 2 x 50 min ST : 2 x 50 min 
– Accuracy describes Integration.
– the accuracy of calculating the integration questions given. 
15 
1112  Students can explain (C2understand) Ordinary Differential Equations of Order 1 and Order 2 and use (C3apply) in Thermodynamics, Kinetics, and Structures.  Order 1 and Order 2 Ordinary Differential Equations in Thermodynamics, Kinetics, and Structures (Orbitals)  Discovery learning
Cooperative learning Problem Based Learning 
listen,
write, ask Learning by digging/looking for information (inquiry) and use that information to solve real problems. 
FF : 2x 50 min
SS : 2 x 50 min ST : 2 x 50 min 
– the accuracy of explaining Ordinary Differential Equations of Order 1 and Order 2.
– the accuracy of calculating Ordinary Differential Equations of Order 1 and Order 2. 
15 
1315  Students can use (C3apply) Ordinary Differential Equations in Thermodynamics, Kinetics, and Structures  Application of Ordinary Differential Equations in Thermodynamics, Kinetics, and Structures (e.g., particles in a onedimensional box)  Discovery learning
Cooperative learning Problem Based Learning 
listen,
write, ask Learning by digging/looking for information (inquiry) and use that information to solve real problems. 
FF : 2x 50 min
SS : 2 x 50 min ST : 2 x 50 min 
– the accuracy of explaining the Application of Ordinary Differential Equations.
– the accuracy of calculating the problems of Application of Ordinary Differential Equations 
25 
16  Final exams  Written exam  90  The truth and completeness of the answer to the question  50 
Reference:
 Kreyszig, E., 1998, “Advanced Engineering Mathematics”, 6th ed., John Wiley & Sons, Inc., New York.
Glossary
GLO = Graduate Learning Outcome
CLO = Course Learning Outcomes
FF = Face to Face Learning
ST = Structured tasks
SS = Self Study