Differential equations in construction engineeringLaajuus (3 cr)
Code: TZLM4350
Credits
3 op
Teaching language
- Finnish
Responsible person
- Antti Kosonen
Objective
Purpose
After the course you will understand how differential equations are used in civil engineering to calculate deflections in beams.
Competencies
Knowledge and understanding of the differential equations at a level necessary to achieve the other programme outcomes.
Learning outcome
You know what differential equations are. You can solve a differential equation of first order using appropriate tools. You understand the role of initial and boundary conditions. You can solve problems related to construction technology.
Content
Using local extremas in calculating deflections in beams. Concept of differential equations and verifying the results and initial and boundary conditions. Solving a differential equation by integrating. Defining the equation for a load and defining the initial and boundary conditions according to the underpinning. Calculating the shear force, the bending moment, the deflection angle and the deflection and determining and analyzing their graphs.
Qualifications
You understand concept of derivation and you can use derivatives in optimization. You understand concept of integrals. You can take the derivatives and integrals of functions by appropriate tools.
Assessment criteria, satisfactory (1)
1: You know the concept of differential equation. You understand how to use differential equations in calculating the deflections in a beam. You can verify the result and the initial and boundary conditions. You can solve the deflection of a beam by a model.
2: You have achieved the desired goals (see the criteria in grade 1). You can solve the deflection of a beam without a model, but your reasoning is sometimes deficient or you make mistakes in calculations.
Assessment criteria, good (3)
3: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in familiar situations showing often the ability to reason completely and calculate flawlessly.
4: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in new situations showing in most cases the ability to reason completely and calculate flawlessly.
Assessment criteria, excellent (5)
5: You have achieved the desired goals (see the criteria in grade 1). You know all the concepts and methods and how to apply them in new situations showing always the ability to combine things, reason completely and calculate flawlessly.
Enrollment
01.08.2024 - 22.08.2024
Timing
21.10.2024 - 15.12.2024
Number of ECTS credits allocated
3 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Main Campus
Teaching languages
- Finnish
Seats
20 - 63
Degree programmes
- Bachelor's Degree Programme in Construction and Civil Engineering
Teachers
- Antti Kosonen
Scheduling groups
- TRY23SA (Capacity: 35. Open UAS: 0.)
- TRY23SB (Capacity: 35. Open UAS: 0.)
Groups
-
TRY23S1Rakennus- ja yhdyskuntatekniikka (AMK)
Small groups
- TRY23SA
- TRY23SB
Objectives
Purpose
After the course you will understand how differential equations are used in civil engineering to calculate deflections in beams.
Competencies
Knowledge and understanding of the differential equations at a level necessary to achieve the other programme outcomes.
Learning outcome
You know what differential equations are. You can solve a differential equation of first order using appropriate tools. You understand the role of initial and boundary conditions. You can solve problems related to construction technology.
Content
Using local extremas in calculating deflections in beams. Concept of differential equations and verifying the results and initial and boundary conditions. Solving a differential equation by integrating. Defining the equation for a load and defining the initial and boundary conditions according to the underpinning. Calculating the shear force, the bending moment, the deflection angle and the deflection and determining and analyzing their graphs.
Time and location
The course takes place 21.10.2024 - 15.12.2024 at the main campus (Rajakatu)
Learning materials and recommended literature
Learning material written by course teacher.
Some good books about the topic that are available at JAMK library in English:
- Beer, F. P. k., Johnston, E. R., DeWolf, J. T. & Mazurek, D. F. 2015. Mechanics of materials. Seventh edition in SI units. New York: McGraw-Hill Education.
- Bedford, A. & Liechti, K. M. 2020. Mechanics of materials. Second Edition. Cham: Springer International Publishing.
Teaching methods
Face-to-face learning. Lesson attendance is mandatory.
It is necessary to actively calculate course exercises to achieve learning goals.
Practical training and working life connections
-
Exam dates and retake possibilities
Final exam in the week starting 9th December 2024
1st resit in the week starting 13th January 2025
2nd resit in the week starting 3rd February 2025
International connections
-
Alternative completion methods
No alternative implementations.
Student workload
3op * 27 h/op = 81 h, of which approximately 20 h are reserved for face-to-face learning and the final exam.
Content scheduling
A more detailed schedule will be presented at the beginning of the course, but the content will be arranged more or less as follows:
- Revision of derivative and integral
- Integration of piecewise defined functions
- Revision of statics and some mechanics of materials
- Shear stress and bending moment in beams as functions of place
- Euler-Bernoulli differential equation and it's solution with different initial conditions
- Buckling of columns
Further information for students
Course assessment is based on final exam and exercises.
If a student enrolled in the course does not show activity within three weeks of the start of the course, the enrollment will be rejected.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
1: You know the concept of differential equation. You understand how to use differential equations in calculating the deflections in a beam. You can verify the result and the initial and boundary conditions. You can solve the deflection of a beam by a model.
2: You have achieved the desired goals (see the criteria in grade 1). You can solve the deflection of a beam without a model, but your reasoning is sometimes deficient or you make mistakes in calculations.
Evaluation criteria, good (3-4)
3: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in familiar situations showing often the ability to reason completely and calculate flawlessly.
4: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in new situations showing in most cases the ability to reason completely and calculate flawlessly.
Evaluation criteria, excellent (5)
5: You have achieved the desired goals (see the criteria in grade 1). You know all the concepts and methods and how to apply them in new situations showing always the ability to combine things, reason completely and calculate flawlessly.
Prerequisites
You understand concept of derivation and you can use derivatives in optimization. You understand concept of integrals. You can take the derivatives and integrals of functions by appropriate tools.
Enrollment
01.08.2023 - 24.08.2023
Timing
06.11.2023 - 28.01.2024
Number of ECTS credits allocated
3 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Main Campus
Teaching languages
- Finnish
Seats
0 - 45
Degree programmes
- Bachelor's Degree Programme in Construction and Civil Engineering
Teachers
- Antti Kosonen
Scheduling groups
- TRY22SA (Capacity: 30. Open UAS: 0.)
- TRY22SB (Capacity: 30. Open UAS: 0.)
Groups
-
TRY22S1Rakennus- ja yhdyskuntatekniikka (AMK)
Small groups
- TRY22SA
- TRY22SB
Objectives
Purpose
After the course you will understand how differential equations are used in civil engineering to calculate deflections in beams.
Competencies
Knowledge and understanding of the differential equations at a level necessary to achieve the other programme outcomes.
Learning outcome
You know what differential equations are. You can solve a differential equation of first order using appropriate tools. You understand the role of initial and boundary conditions. You can solve problems related to construction technology.
Content
Using local extremas in calculating deflections in beams. Concept of differential equations and verifying the results and initial and boundary conditions. Solving a differential equation by integrating. Defining the equation for a load and defining the initial and boundary conditions according to the underpinning. Calculating the shear force, the bending moment, the deflection angle and the deflection and determining and analyzing their graphs.
Time and location
The course takes place 6.11.2023 - 28.1.2024 at the main campus (Rajakatu)
Learning materials and recommended literature
Learning material written by course teacher.
Some good books about the topic that are available at JAMK library in English:
- Beer, F. P. k., Johnston, E. R., DeWolf, J. T. & Mazurek, D. F. 2015. Mechanics of materials. Seventh edition in SI units. New York: McGraw-Hill Education.
- Bedford, A. & Liechti, K. M. 2020. Mechanics of materials. Second Edition. Cham: Springer International Publishing.
Teaching methods
face-to-face learning
Practical training and working life connections
-
Exam dates and retake possibilities
Final exam in the week starting 22 January 2024
1st resit in the week starting 19 February 2024
2nd resit in the week starting 18 March 2024
International connections
-
Alternative completion methods
No alternative implementations.
Student workload
3op * 27 h/op = 81 h, of which approximately 30 h are reserved for face-to-face learning and the final exam.
Content scheduling
A more detailed schedule will be presented at the beginning of the course, but the content will be arranged more or less as follows:
- Revision of derivative and integral
- Integration of piecewise defined functions
- Revision of statics and some mechanics of materials
- Shear stress and bending moment in beams as functions of place
- Euler-Bernoulli differential equation and it's solution with different initial conditions
- Buckling of columns
Further information for students
Course assessment is based on final exam and exercises.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
1: You know the concept of differential equation. You understand how to use differential equations in calculating the deflections in a beam. You can verify the result and the initial and boundary conditions. You can solve the deflection of a beam by a model.
2: You have achieved the desired goals (see the criteria in grade 1). You can solve the deflection of a beam without a model, but your reasoning is sometimes deficient or you make mistakes in calculations.
Evaluation criteria, good (3-4)
3: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in familiar situations showing often the ability to reason completely and calculate flawlessly.
4: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in new situations showing in most cases the ability to reason completely and calculate flawlessly.
Evaluation criteria, excellent (5)
5: You have achieved the desired goals (see the criteria in grade 1). You know all the concepts and methods and how to apply them in new situations showing always the ability to combine things, reason completely and calculate flawlessly.
Prerequisites
You understand concept of derivation and you can use derivatives in optimization. You understand concept of integrals. You can take the derivatives and integrals of functions by appropriate tools.
Enrollment
27.04.2023 - 31.05.2023
Timing
01.05.2023 - 31.08.2023
Number of ECTS credits allocated
3 op
Virtual portion
3 op
Mode of delivery
Online learning
Unit
School of Technology
Campus
Main Campus
Teaching languages
- Finnish
Seats
0 - 10
Degree programmes
- Bachelor's Degree Programme in Construction and Civil Engineering
Teachers
- Antti Kosonen
Groups
-
TRY21S1Rakennus- ja yhdyskuntatekniikka (AMK)
Objectives
Purpose
After the course you will understand how differential equations are used in civil engineering to calculate deflections in beams.
Competencies
Knowledge and understanding of the differential equations at a level necessary to achieve the other programme outcomes.
Learning outcome
You know what differential equations are. You can solve a differential equation of first order using appropriate tools. You understand the role of initial and boundary conditions. You can solve problems related to construction technology.
Content
Using local extremas in calculating deflections in beams. Concept of differential equations and verifying the results and initial and boundary conditions. Solving a differential equation by integrating. Defining the equation for a load and defining the initial and boundary conditions according to the underpinning. Calculating the shear force, the bending moment, the deflection angle and the deflection and determining and analyzing their graphs.
Learning materials and recommended literature
Learning material written by course teacher and video recordings.
Some good books about the topic that are available at JAMK library in English:
- Beer, F. P. k., Johnston, E. R., DeWolf, J. T. & Mazurek, D. F. 2015. Mechanics of materials. Seventh edition in SI units. New York: McGraw-Hill Education.
- Bedford, A. & Liechti, K. M. 2020. Mechanics of materials. Second Edition. Cham: Springer International Publishing.
Teaching methods
E-learning: Independent study.
Practical training and working life connections
-
Exam dates and retake possibilities
Final exam at Rajakatu campus /online August 23
1st resit September 11 at campus / online
2nd resit October 2 at campus / online
International connections
-
Alternative completion methods
Lähitoteutus syksyllä 2023.
Student workload
3op * 27 h/op = 81 h of independent study
Content scheduling
The student can complete the course at their own pace during the summer of 2023.
Further information for students
Assessment is based solely on the final exam.
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
1: You know the concept of differential equation. You understand how to use differential equations in calculating the deflections in a beam. You can verify the result and the initial and boundary conditions. You can solve the deflection of a beam by a model.
2: You have achieved the desired goals (see the criteria in grade 1). You can solve the deflection of a beam without a model, but your reasoning is sometimes deficient or you make mistakes in calculations.
Evaluation criteria, good (3-4)
3: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in familiar situations showing often the ability to reason completely and calculate flawlessly.
4: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in new situations showing in most cases the ability to reason completely and calculate flawlessly.
Evaluation criteria, excellent (5)
5: You have achieved the desired goals (see the criteria in grade 1). You know all the concepts and methods and how to apply them in new situations showing always the ability to combine things, reason completely and calculate flawlessly.
Prerequisites
You understand concept of derivation and you can use derivatives in optimization. You understand concept of integrals. You can take the derivatives and integrals of functions by appropriate tools.
Enrollment
01.08.2022 - 25.08.2022
Timing
29.08.2022 - 13.11.2022
Number of ECTS credits allocated
3 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Main Campus
Teaching languages
- Finnish
Seats
0 - 50
Degree programmes
- Bachelor's Degree Programme in Construction and Civil Engineering
Teachers
- Antti Kosonen
Teacher in charge
Antti Kosonen
Scheduling groups
- TRY21SA (Capacity: 30. Open UAS: 0.)
- TRY21SB (Capacity: 30. Open UAS: 0.)
Groups
-
TRY21S1Rakennus- ja yhdyskuntatekniikka (AMK)
Small groups
- TRY21SA
- TRY21SB
Objectives
Purpose
After the course you will understand how differential equations are used in civil engineering to calculate deflections in beams.
Competencies
Knowledge and understanding of the differential equations at a level necessary to achieve the other programme outcomes.
Learning outcome
You know what differential equations are. You can solve a differential equation of first order using appropriate tools. You understand the role of initial and boundary conditions. You can solve problems related to construction technology.
Content
Using local extremas in calculating deflections in beams. Concept of differential equations and verifying the results and initial and boundary conditions. Solving a differential equation by integrating. Defining the equation for a load and defining the initial and boundary conditions according to the underpinning. Calculating the shear force, the bending moment, the deflection angle and the deflection and determining and analyzing their graphs.
Time and location
The course takes place 29.8. - 13.11. at the main campus (Rajakatu)
Learning materials and recommended literature
Learning material written by course teacher.
Some good books about the topic that are available at JAMK library in English:
- Beer, F. P. k., Johnston, E. R., DeWolf, J. T. & Mazurek, D. F. 2015. Mechanics of materials. Seventh edition in SI units. New York: McGraw-Hill Education.
- Bedford, A. & Liechti, K. M. 2020. Mechanics of materials. Second Edition. Cham: Springer International Publishing.
Teaching methods
face-to-face learning
Practical training and working life connections
-
Exam dates and retake possibilities
Final exam: 10.11.2022
1. resit: week of 12.12.2022
2. resit: week of 16.1.2023
International connections
-
Alternative completion methods
No alternative implementations.
Student workload
3op * 27 h/op = 81 h, of which approximately 30 h are reserved for face-to-face learning and the final exam.
Content scheduling
A more detailed schedule will be presented at the beginning of the course, but the content will be arranged more or less as follows:
- Revision of derivative and integral and the concept of a differential equation
- Integration of piecewise defined functions
- Revision of statics and some mechanics of materials
- Shear stress and bending moment in beams as functions of place
- Euler-Bernoulli differential equation and it's solution with different initial conditions
Further information for students
Final exam, exercises
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
1: You know the concept of differential equation. You understand how to use differential equations in calculating the deflections in a beam. You can verify the result and the initial and boundary conditions. You can solve the deflection of a beam by a model.
2: You have achieved the desired goals (see the criteria in grade 1). You can solve the deflection of a beam without a model, but your reasoning is sometimes deficient or you make mistakes in calculations.
Evaluation criteria, good (3-4)
3: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in familiar situations showing often the ability to reason completely and calculate flawlessly.
4: You have achieved the desired goals (see the criteria in grade 1). You know most of the concepts and methods and how to apply them in new situations showing in most cases the ability to reason completely and calculate flawlessly.
Evaluation criteria, excellent (5)
5: You have achieved the desired goals (see the criteria in grade 1). You know all the concepts and methods and how to apply them in new situations showing always the ability to combine things, reason completely and calculate flawlessly.
Prerequisites
You understand concept of derivation and you can use derivatives in optimization. You understand concept of integrals. You can take the derivatives and integrals of functions by appropriate tools.