Data NetworksLaajuus (5 cr)
Code: TT00CD70
Credits
5 op
Teaching language
- Finnish
- English
Responsible person
- Pasi Hyytiäinen
Objective
You learn the structure, protocols of data networks used by computers (and other end devices). You also know the principles of planning a data network.
You are familiar with protocols and data transmission principles used on the Internet. You know the layers of the OSI model and identify the technologies and protocols used on each layer of the model. You can design a local area network using switches, routers, workstations, and servers. You are able to design cabling, switching topology, and routing scheme to run the data network. You know the different devices used on a network (e.g. switches, routers, firewalls, wireless base stations). You can change, handle and save the configuration used in network devices. You know how local area networks interconnect to one another through wide area networks.
EUR-ACE Knowledge and understanding
You know the main modeling methods of data networks and you have knowledge and understanding of data networks and their effects. You know the basic principles of network design and how to configure network devices.
EUR-ACE Engineering practice
You can apply data network skills to communication between devices.
Content
In this course, you will learn the principles of network structure and protocol design, as well as the principles of Internet communication. You will master the layers of the OSI model and be able to design and implement local area networks using switches, routers and servers. You will learn how to design cabling and routing plans and how to handle network equipment configurations. You will also understand how to efficiently connect local area networks to backbone networks.
The contents stated through the OSI model:
Layer 1
Physical cabling (copper, fiber)
Wireless Local Area Networks
Basic modulations in data transfer
Devices
Layer 2
Ethernet switching
Network Segmentation (VLANs)
Loop detection (Spanning Tree)
MAC addressing
Layer 3
IPv4 and IPv6 addressing, subnetting
Routing (Static, OSPF and BGP)
DHCP, ARP
Layer 4
TCP and UDP
Layers 5 to 7
SSH, HTTP, DNS, SMTP
In addition, best practices in network design and configuration management are covered in the course.
Qualifications
Linux basics
Assessment criteria, satisfactory (1)
Sufficient (1)
The student knows the theory on network protocols sufficiently and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Satisfactory (2)
The student knows the theory on network protocols satisfactorily and is able to recognize existing solutions. The student can design and implement some parts of a small-scale network infrastructure based on given requirement specification.
Assessment criteria, good (3)
Good (3)
The student has good knowledge of the theory on network protocols and is able to analyze existing solutions. The student is able to design and implement most parts of a network infrastructure based on given requirement specification.
Very good (4)
The student masters the theory on network protocols very well and is able to analyze existing solutions. The student is able to plan and implement almost all parts of a network infrastructure based on given requirement specification.
Assessment criteria, excellent (5)
Excellent (5)
The student has excellent command of the theory on network protocols and is able to analyze existing solutions and create new solutions. The student is able to design and implement all parts of a large-scale network infrastructure based on given requirement specification.
Assessment criteria, approved/failed
The student has sufficient knowledge of the theory on network protocols and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
5 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Esa Hintikka
- It Instituutti
Groups
-
TTV24S1Tieto- ja viestintätekniikka (AMK)
Objectives
You learn the structure, protocols of data networks used by computers (and other end devices). You also know the principles of planning a data network.
You are familiar with protocols and data transmission principles used on the Internet. You know the layers of the OSI model and identify the technologies and protocols used on each layer of the model. You can design a local area network using switches, routers, workstations, and servers. You are able to design cabling, switching topology, and routing scheme to run the data network. You know the different devices used on a network (e.g. switches, routers, firewalls, wireless base stations). You can change, handle and save the configuration used in network devices. You know how local area networks interconnect to one another through wide area networks.
EUR-ACE Knowledge and understanding
You know the main modeling methods of data networks and you have knowledge and understanding of data networks and their effects. You know the basic principles of network design and how to configure network devices.
EUR-ACE Engineering practice
You can apply data network skills to communication between devices.
Content
In this course, you will learn the principles of network structure and protocol design, as well as the principles of Internet communication. You will master the layers of the OSI model and be able to design and implement local area networks using switches, routers and servers. You will learn how to design cabling and routing plans and how to handle network equipment configurations. You will also understand how to efficiently connect local area networks to backbone networks.
The contents stated through the OSI model:
Layer 1
Physical cabling (copper, fiber)
Wireless Local Area Networks
Basic modulations in data transfer
Devices
Layer 2
Ethernet switching
Network Segmentation (VLANs)
Loop detection (Spanning Tree)
MAC addressing
Layer 3
IPv4 and IPv6 addressing, subnetting
Routing (Static, OSPF and BGP)
DHCP, ARP
Layer 4
TCP and UDP
Layers 5 to 7
SSH, HTTP, DNS, SMTP
In addition, best practices in network design and configuration management are covered in the course.
Learning materials and recommended literature
Materials in the e-learning environment.
Teaching methods
- lectures
- independent study
- small group learning
- exercises
- learning tasks
- seminars
Practical training and working life connections
- visiting lecturers
- projects
Exam dates and retake possibilities
The possible date and method of the exam will be announced in the course opening.
Alternative completion methods
The admission procedures are described in the degree rule and the study guide. The teacher of the course will give you more information on possible specific course practices.
Student workload
One credit (1 Cr) corresponds to an average of 27 hours of work.
- lectures 52 h
- exercises 15 h
- assignment 35 h
- independent study 30 h
- company visits 3 h
Total 135 h
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient (1)
The student knows the theory on network protocols sufficiently and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Satisfactory (2)
The student knows the theory on network protocols satisfactorily and is able to recognize existing solutions. The student can design and implement some parts of a small-scale network infrastructure based on given requirement specification.
Evaluation criteria, good (3-4)
Good (3)
The student has good knowledge of the theory on network protocols and is able to analyze existing solutions. The student is able to design and implement most parts of a network infrastructure based on given requirement specification.
Very good (4)
The student masters the theory on network protocols very well and is able to analyze existing solutions. The student is able to plan and implement almost all parts of a network infrastructure based on given requirement specification.
Evaluation criteria, excellent (5)
Excellent (5)
The student has excellent command of the theory on network protocols and is able to analyze existing solutions and create new solutions. The student is able to design and implement all parts of a large-scale network infrastructure based on given requirement specification.
Evaluation criteria, pass/failed
The student has sufficient knowledge of the theory on network protocols and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Prerequisites
Linux basics
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
5 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- English
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Esa Hintikka
Groups
-
TIC24S1Bachelor's Degree Programme in Information and Communications Technology
-
ZJATIC24S1Avoin amk,ICT, Information and Communication Technology, Päivä
Objectives
You learn the structure, protocols of data networks used by computers (and other end devices). You also know the principles of planning a data network.
You are familiar with protocols and data transmission principles used on the Internet. You know the layers of the OSI model and identify the technologies and protocols used on each layer of the model. You can design a local area network using switches, routers, workstations, and servers. You are able to design cabling, switching topology, and routing scheme to run the data network. You know the different devices used on a network (e.g. switches, routers, firewalls, wireless base stations). You can change, handle and save the configuration used in network devices. You know how local area networks interconnect to one another through wide area networks.
EUR-ACE Knowledge and understanding
You know the main modeling methods of data networks and you have knowledge and understanding of data networks and their effects. You know the basic principles of network design and how to configure network devices.
EUR-ACE Engineering practice
You can apply data network skills to communication between devices.
Content
In this course, you will learn the principles of network structure and protocol design, as well as the principles of Internet communication. You will master the layers of the OSI model and be able to design and implement local area networks using switches, routers and servers. You will learn how to design cabling and routing plans and how to handle network equipment configurations. You will also understand how to efficiently connect local area networks to backbone networks.
The contents stated through the OSI model:
Layer 1
Physical cabling (copper, fiber)
Wireless Local Area Networks
Basic modulations in data transfer
Devices
Layer 2
Ethernet switching
Network Segmentation (VLANs)
Loop detection (Spanning Tree)
MAC addressing
Layer 3
IPv4 and IPv6 addressing, subnetting
Routing (Static, OSPF and BGP)
DHCP, ARP
Layer 4
TCP and UDP
Layers 5 to 7
SSH, HTTP, DNS, SMTP
In addition, best practices in network design and configuration management are covered in the course.
Learning materials and recommended literature
Materials in the e-learning environment.
Teaching methods
- lectures
- independent study
- small group learning
- exercises
- learning tasks
- seminars
Practical training and working life connections
- visiting lecturers
- projects
Exam dates and retake possibilities
The possible date and method of the exam will be announced in the course opening.
Alternative completion methods
The admission procedures are described in the degree rule and the study guide. The teacher of the course will give you more information on possible specific course practices.
Student workload
One credit (1 Cr) corresponds to an average of 27 hours of work.
- lectures 52 h
- exercises 15 h
- assignment 35 h
- independent study 30 h
- company visits 3 h
Total 135 h
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient (1)
The student knows the theory on network protocols sufficiently and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Satisfactory (2)
The student knows the theory on network protocols satisfactorily and is able to recognize existing solutions. The student can design and implement some parts of a small-scale network infrastructure based on given requirement specification.
Evaluation criteria, good (3-4)
Good (3)
The student has good knowledge of the theory on network protocols and is able to analyze existing solutions. The student is able to design and implement most parts of a network infrastructure based on given requirement specification.
Very good (4)
The student masters the theory on network protocols very well and is able to analyze existing solutions. The student is able to plan and implement almost all parts of a network infrastructure based on given requirement specification.
Evaluation criteria, excellent (5)
Excellent (5)
The student has excellent command of the theory on network protocols and is able to analyze existing solutions and create new solutions. The student is able to design and implement all parts of a large-scale network infrastructure based on given requirement specification.
Evaluation criteria, pass/failed
The student has sufficient knowledge of the theory on network protocols and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Prerequisites
Linux basics
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
5 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- English
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Esa Hintikka
Groups
-
TIC24S2Bachelor's Degree Programme in Information and Communications Technology
Objectives
You learn the structure, protocols of data networks used by computers (and other end devices). You also know the principles of planning a data network.
You are familiar with protocols and data transmission principles used on the Internet. You know the layers of the OSI model and identify the technologies and protocols used on each layer of the model. You can design a local area network using switches, routers, workstations, and servers. You are able to design cabling, switching topology, and routing scheme to run the data network. You know the different devices used on a network (e.g. switches, routers, firewalls, wireless base stations). You can change, handle and save the configuration used in network devices. You know how local area networks interconnect to one another through wide area networks.
EUR-ACE Knowledge and understanding
You know the main modeling methods of data networks and you have knowledge and understanding of data networks and their effects. You know the basic principles of network design and how to configure network devices.
EUR-ACE Engineering practice
You can apply data network skills to communication between devices.
Content
In this course, you will learn the principles of network structure and protocol design, as well as the principles of Internet communication. You will master the layers of the OSI model and be able to design and implement local area networks using switches, routers and servers. You will learn how to design cabling and routing plans and how to handle network equipment configurations. You will also understand how to efficiently connect local area networks to backbone networks.
The contents stated through the OSI model:
Layer 1
Physical cabling (copper, fiber)
Wireless Local Area Networks
Basic modulations in data transfer
Devices
Layer 2
Ethernet switching
Network Segmentation (VLANs)
Loop detection (Spanning Tree)
MAC addressing
Layer 3
IPv4 and IPv6 addressing, subnetting
Routing (Static, OSPF and BGP)
DHCP, ARP
Layer 4
TCP and UDP
Layers 5 to 7
SSH, HTTP, DNS, SMTP
In addition, best practices in network design and configuration management are covered in the course.
Learning materials and recommended literature
Materials in the e-learning environment.
Teaching methods
- lectures
- independent study
- small group learning
- exercises
- learning tasks
- seminars
Practical training and working life connections
- visiting lecturers
- projects
Exam dates and retake possibilities
The possible date and method of the exam will be announced in the course opening.
Alternative completion methods
The admission procedures are described in the degree rule and the study guide. The teacher of the course will give you more information on possible specific course practices.
Student workload
One credit (1 Cr) corresponds to an average of 27 hours of work.
- lectures 52 h
- exercises 15 h
- assignment 35 h
- independent study 30 h
- company visits 3 h
Total 135 h
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient (1)
The student knows the theory on network protocols sufficiently and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Satisfactory (2)
The student knows the theory on network protocols satisfactorily and is able to recognize existing solutions. The student can design and implement some parts of a small-scale network infrastructure based on given requirement specification.
Evaluation criteria, good (3-4)
Good (3)
The student has good knowledge of the theory on network protocols and is able to analyze existing solutions. The student is able to design and implement most parts of a network infrastructure based on given requirement specification.
Very good (4)
The student masters the theory on network protocols very well and is able to analyze existing solutions. The student is able to plan and implement almost all parts of a network infrastructure based on given requirement specification.
Evaluation criteria, excellent (5)
Excellent (5)
The student has excellent command of the theory on network protocols and is able to analyze existing solutions and create new solutions. The student is able to design and implement all parts of a large-scale network infrastructure based on given requirement specification.
Evaluation criteria, pass/failed
The student has sufficient knowledge of the theory on network protocols and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Prerequisites
Linux basics
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
5 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Esa Hintikka
Groups
-
ZJATTV24S2Avoin amk, Tieto- ja viestintätekniikka, Päivä
-
TTV24S2Tieto- ja viestintätekniikka (AMK)
Objectives
You learn the structure, protocols of data networks used by computers (and other end devices). You also know the principles of planning a data network.
You are familiar with protocols and data transmission principles used on the Internet. You know the layers of the OSI model and identify the technologies and protocols used on each layer of the model. You can design a local area network using switches, routers, workstations, and servers. You are able to design cabling, switching topology, and routing scheme to run the data network. You know the different devices used on a network (e.g. switches, routers, firewalls, wireless base stations). You can change, handle and save the configuration used in network devices. You know how local area networks interconnect to one another through wide area networks.
EUR-ACE Knowledge and understanding
You know the main modeling methods of data networks and you have knowledge and understanding of data networks and their effects. You know the basic principles of network design and how to configure network devices.
EUR-ACE Engineering practice
You can apply data network skills to communication between devices.
Content
In this course, you will learn the principles of network structure and protocol design, as well as the principles of Internet communication. You will master the layers of the OSI model and be able to design and implement local area networks using switches, routers and servers. You will learn how to design cabling and routing plans and how to handle network equipment configurations. You will also understand how to efficiently connect local area networks to backbone networks.
The contents stated through the OSI model:
Layer 1
Physical cabling (copper, fiber)
Wireless Local Area Networks
Basic modulations in data transfer
Devices
Layer 2
Ethernet switching
Network Segmentation (VLANs)
Loop detection (Spanning Tree)
MAC addressing
Layer 3
IPv4 and IPv6 addressing, subnetting
Routing (Static, OSPF and BGP)
DHCP, ARP
Layer 4
TCP and UDP
Layers 5 to 7
SSH, HTTP, DNS, SMTP
In addition, best practices in network design and configuration management are covered in the course.
Learning materials and recommended literature
Materials in the e-learning environment.
Teaching methods
- lectures
- independent study
- small group learning
- exercises
- learning tasks
- seminars
Practical training and working life connections
- visiting lecturers
- projects
Exam dates and retake possibilities
The possible date and method of the exam will be announced in the course opening.
Alternative completion methods
The admission procedures are described in the degree rule and the study guide. The teacher of the course will give you more information on possible specific course practices.
Student workload
One credit (1 Cr) corresponds to an average of 27 hours of work.
- lectures 52 h
- exercises 15 h
- assignment 35 h
- independent study 30 h
- company visits 3 h
Total 135 h
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient (1)
The student knows the theory on network protocols sufficiently and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Satisfactory (2)
The student knows the theory on network protocols satisfactorily and is able to recognize existing solutions. The student can design and implement some parts of a small-scale network infrastructure based on given requirement specification.
Evaluation criteria, good (3-4)
Good (3)
The student has good knowledge of the theory on network protocols and is able to analyze existing solutions. The student is able to design and implement most parts of a network infrastructure based on given requirement specification.
Very good (4)
The student masters the theory on network protocols very well and is able to analyze existing solutions. The student is able to plan and implement almost all parts of a network infrastructure based on given requirement specification.
Evaluation criteria, excellent (5)
Excellent (5)
The student has excellent command of the theory on network protocols and is able to analyze existing solutions and create new solutions. The student is able to design and implement all parts of a large-scale network infrastructure based on given requirement specification.
Evaluation criteria, pass/failed
The student has sufficient knowledge of the theory on network protocols and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Prerequisites
Linux basics
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
5 op
Mode of delivery
Face-to-face
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Esa Hintikka
Groups
-
TTV24S3Tieto- ja viestintätekniikka (AMK)
-
ZJATTV24S3Avoin amk, Tieto- ja viestintätekniikka, Päivä
Objectives
You learn the structure, protocols of data networks used by computers (and other end devices). You also know the principles of planning a data network.
You are familiar with protocols and data transmission principles used on the Internet. You know the layers of the OSI model and identify the technologies and protocols used on each layer of the model. You can design a local area network using switches, routers, workstations, and servers. You are able to design cabling, switching topology, and routing scheme to run the data network. You know the different devices used on a network (e.g. switches, routers, firewalls, wireless base stations). You can change, handle and save the configuration used in network devices. You know how local area networks interconnect to one another through wide area networks.
EUR-ACE Knowledge and understanding
You know the main modeling methods of data networks and you have knowledge and understanding of data networks and their effects. You know the basic principles of network design and how to configure network devices.
EUR-ACE Engineering practice
You can apply data network skills to communication between devices.
Content
In this course, you will learn the principles of network structure and protocol design, as well as the principles of Internet communication. You will master the layers of the OSI model and be able to design and implement local area networks using switches, routers and servers. You will learn how to design cabling and routing plans and how to handle network equipment configurations. You will also understand how to efficiently connect local area networks to backbone networks.
The contents stated through the OSI model:
Layer 1
Physical cabling (copper, fiber)
Wireless Local Area Networks
Basic modulations in data transfer
Devices
Layer 2
Ethernet switching
Network Segmentation (VLANs)
Loop detection (Spanning Tree)
MAC addressing
Layer 3
IPv4 and IPv6 addressing, subnetting
Routing (Static, OSPF and BGP)
DHCP, ARP
Layer 4
TCP and UDP
Layers 5 to 7
SSH, HTTP, DNS, SMTP
In addition, best practices in network design and configuration management are covered in the course.
Learning materials and recommended literature
Materials in the e-learning environment.
Teaching methods
- lectures
- independent study
- small group learning
- exercises
- learning tasks
- seminars
Practical training and working life connections
- visiting lecturers
- projects
Exam dates and retake possibilities
The possible date and method of the exam will be announced in the course opening.
Alternative completion methods
The admission procedures are described in the degree rule and the study guide. The teacher of the course will give you more information on possible specific course practices.
Student workload
One credit (1 Cr) corresponds to an average of 27 hours of work.
- lectures 52 h
- exercises 15 h
- assignment 35 h
- independent study 30 h
- company visits 3 h
Total 135 h
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient (1)
The student knows the theory on network protocols sufficiently and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Satisfactory (2)
The student knows the theory on network protocols satisfactorily and is able to recognize existing solutions. The student can design and implement some parts of a small-scale network infrastructure based on given requirement specification.
Evaluation criteria, good (3-4)
Good (3)
The student has good knowledge of the theory on network protocols and is able to analyze existing solutions. The student is able to design and implement most parts of a network infrastructure based on given requirement specification.
Very good (4)
The student masters the theory on network protocols very well and is able to analyze existing solutions. The student is able to plan and implement almost all parts of a network infrastructure based on given requirement specification.
Evaluation criteria, excellent (5)
Excellent (5)
The student has excellent command of the theory on network protocols and is able to analyze existing solutions and create new solutions. The student is able to design and implement all parts of a large-scale network infrastructure based on given requirement specification.
Evaluation criteria, pass/failed
The student has sufficient knowledge of the theory on network protocols and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Prerequisites
Linux basics
Enrollment
18.11.2024 - 09.01.2025
Timing
13.01.2025 - 30.04.2025
Number of ECTS credits allocated
5 op
Virtual portion
5 op
Mode of delivery
Online learning
Unit
School of Technology
Campus
Lutakko Campus
Teaching languages
- Finnish
Seats
0 - 35
Degree programmes
- Bachelor's Degree Programme in Information and Communications Technology
Teachers
- Esa Hintikka
Groups
-
TTV24SMTieto- ja viestintätekniikka (AMK)
-
ZJATTV24SMAvoin amk, Tieto- ja viestintätekniikka, Monimuoto
Objectives
You learn the structure, protocols of data networks used by computers (and other end devices). You also know the principles of planning a data network.
You are familiar with protocols and data transmission principles used on the Internet. You know the layers of the OSI model and identify the technologies and protocols used on each layer of the model. You can design a local area network using switches, routers, workstations, and servers. You are able to design cabling, switching topology, and routing scheme to run the data network. You know the different devices used on a network (e.g. switches, routers, firewalls, wireless base stations). You can change, handle and save the configuration used in network devices. You know how local area networks interconnect to one another through wide area networks.
EUR-ACE Knowledge and understanding
You know the main modeling methods of data networks and you have knowledge and understanding of data networks and their effects. You know the basic principles of network design and how to configure network devices.
EUR-ACE Engineering practice
You can apply data network skills to communication between devices.
Content
In this course, you will learn the principles of network structure and protocol design, as well as the principles of Internet communication. You will master the layers of the OSI model and be able to design and implement local area networks using switches, routers and servers. You will learn how to design cabling and routing plans and how to handle network equipment configurations. You will also understand how to efficiently connect local area networks to backbone networks.
The contents stated through the OSI model:
Layer 1
Physical cabling (copper, fiber)
Wireless Local Area Networks
Basic modulations in data transfer
Devices
Layer 2
Ethernet switching
Network Segmentation (VLANs)
Loop detection (Spanning Tree)
MAC addressing
Layer 3
IPv4 and IPv6 addressing, subnetting
Routing (Static, OSPF and BGP)
DHCP, ARP
Layer 4
TCP and UDP
Layers 5 to 7
SSH, HTTP, DNS, SMTP
In addition, best practices in network design and configuration management are covered in the course.
Learning materials and recommended literature
Saharinen, Karo. 2021. Data Networks. http://datanetworks.pages.labranet.jamk.fi.
Teaching methods
- Lectures (flipped learning video)
- Practical exercises
- Demonstration of skills as personal assignments
Practical training and working life connections
The course will contain points of view from the industry on how data networks operate in Finland.
Exam dates and retake possibilities
The course will use JAMK's Exam Studio where you can reserve exam times based on your own calendar/timetable.
Alternative completion methods
The admission procedures are described in the degree rule and the study guide. The teacher of the course will give you more information on possible specific course practices.
Student workload
5 ECTS * 27 h = 135 hours where,
33,25 h theory material, where
- 13,25 h = Video material/Lectures based on the text
- 20 h = re-reading the material
81,75 h = ~4,8h per exercise (if grade 5 is your goal)
15 h = Self-study (reflecting, going through additional material, troubleshooting, using relevant tools)
5 h = Exam (this includes retakes if necessary)
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient (1)
The student knows the theory on network protocols sufficiently and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Satisfactory (2)
The student knows the theory on network protocols satisfactorily and is able to recognize existing solutions. The student can design and implement some parts of a small-scale network infrastructure based on given requirement specification.
Evaluation criteria, good (3-4)
Good (3)
The student has good knowledge of the theory on network protocols and is able to analyze existing solutions. The student is able to design and implement most parts of a network infrastructure based on given requirement specification.
Very good (4)
The student masters the theory on network protocols very well and is able to analyze existing solutions. The student is able to plan and implement almost all parts of a network infrastructure based on given requirement specification.
Evaluation criteria, excellent (5)
Excellent (5)
The student has excellent command of the theory on network protocols and is able to analyze existing solutions and create new solutions. The student is able to design and implement all parts of a large-scale network infrastructure based on given requirement specification.
Evaluation criteria, pass/failed
The student has sufficient knowledge of the theory on network protocols and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Prerequisites
Linux basics
Timing
30.08.2024 - 31.07.2025
Number of ECTS credits allocated
5 op
Virtual portion
5 op
Mode of delivery
Online learning
Unit
School of Technology
Teaching languages
- Finnish
Degree programmes
- Bachelor's Degree Programme in Electrical and Automation Engineering
- Bachelor's Degree Programme in Information and Communications Technology
- Bachelor's Degree Programme in Automation and Robotics
Teachers
- Pasi Hyytiäinen
Groups
-
ZJA24STINOAvoin amk, ICT,Nonstop, Verkko
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ZJA24STIDIAvoin amk, Digiosaaja, Verkko
-
ZJA25KTINOAvoin amk,ICT, Nonstop, Verkko
-
ZJA24KTIDIAvoin amk, ICT Digiosaaja, Verkko
Objectives
You learn the structure, protocols of data networks used by computers (and other end devices). You also know the principles of planning a data network.
You are familiar with protocols and data transmission principles used on the Internet. You know the layers of the OSI model and identify the technologies and protocols used on each layer of the model. You can design a local area network using switches, routers, workstations, and servers. You are able to design cabling, switching topology, and routing scheme to run the data network. You know the different devices used on a network (e.g. switches, routers, firewalls, wireless base stations). You can change, handle and save the configuration used in network devices. You know how local area networks interconnect to one another through wide area networks.
EUR-ACE Knowledge and understanding
You know the main modeling methods of data networks and you have knowledge and understanding of data networks and their effects. You know the basic principles of network design and how to configure network devices.
EUR-ACE Engineering practice
You can apply data network skills to communication between devices.
Content
In this course, you will learn the principles of network structure and protocol design, as well as the principles of Internet communication. You will master the layers of the OSI model and be able to design and implement local area networks using switches, routers and servers. You will learn how to design cabling and routing plans and how to handle network equipment configurations. You will also understand how to efficiently connect local area networks to backbone networks.
The contents stated through the OSI model:
Layer 1
Physical cabling (copper, fiber)
Wireless Local Area Networks
Basic modulations in data transfer
Devices
Layer 2
Ethernet switching
Network Segmentation (VLANs)
Loop detection (Spanning Tree)
MAC addressing
Layer 3
IPv4 and IPv6 addressing, subnetting
Routing (Static, OSPF and BGP)
DHCP, ARP
Layer 4
TCP and UDP
Layers 5 to 7
SSH, HTTP, DNS, SMTP
In addition, best practices in network design and configuration management are covered in the course.
Learning materials and recommended literature
Saharinen, Karo. 2021. Data Networks. http://datanetworks.pages.labranet.jamk.fi.
Teaching methods
- Lectures (flipped learning video)
- Practical exercises
- Demonstration of skills as personal assignments
Practical training and working life connections
The course will contain points of view from the industry on how data networks operate in Finland.
Exam dates and retake possibilities
The course will use JAMK's Exam Studio where you can reserve exam times based on your own calendar/timetable.
Alternative completion methods
The course can be done by accredition of competence. Agree upon the accreditation with the course lecturer. More information about accreditation in the degree regulations of JAMK and the study guide.
Student workload
5 ECTS * 27 h = 135 hours where,
33,25 h theory material, where
- 13,25 h = Video material/Lectures based on the text
- 20 h = re-reading the material
81,75 h = ~4,8h per exercise (if grade 5 is your goal)
15 h = Self-study (reflecting, going through additional material, troubleshooting, using relevant tools)
5 h = Exam (this includes retakes if necessary)
Evaluation scale
0-5
Evaluation criteria, satisfactory (1-2)
Sufficient (1)
The student knows the theory on network protocols sufficiently and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Satisfactory (2)
The student knows the theory on network protocols satisfactorily and is able to recognize existing solutions. The student can design and implement some parts of a small-scale network infrastructure based on given requirement specification.
Evaluation criteria, good (3-4)
Good (3)
The student has good knowledge of the theory on network protocols and is able to analyze existing solutions. The student is able to design and implement most parts of a network infrastructure based on given requirement specification.
Very good (4)
The student masters the theory on network protocols very well and is able to analyze existing solutions. The student is able to plan and implement almost all parts of a network infrastructure based on given requirement specification.
Evaluation criteria, excellent (5)
Excellent (5)
The student has excellent command of the theory on network protocols and is able to analyze existing solutions and create new solutions. The student is able to design and implement all parts of a large-scale network infrastructure based on given requirement specification.
Evaluation criteria, pass/failed
The student has sufficient knowledge of the theory on network protocols and is able to recognize some sections of existing solutions. The student can design and implement few parts of a small-scale network infrastructure based on given requirement specification.
Prerequisites
Linux basics