Study Guide

Objective

Student knows how the development in industrial internet and internet of things affects to the manufacturing industry and services.
Student knows how to develop IoT services and utilize cloud computing. Student knows how to send data from industrial processes and devices to IoT services. Student knows the impact of industrial internet of things on sustainable development.

Content

Principles of industrial internet
Cloud services and IoT platforms
Standards and protocols used with industrial internet (OPC UA, MQTT, AMQP)
Web development for IoT

Materials

To be announced at the beginning of the course

Teaching methods

Lectures and exercises

Exam schedules

The exam is in the last lesson

Student workload

Lectures 37 %, independent studying 63 %.

Evaluation scale

1-5

Assessment criteria, satisfactory (1)

Student knows the basics of industrial internet and cloud services. Student can make a simple program which transmits data from simulated automation system to a cloud service.

Assessment criteria, good (3)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a simple web-based application, which visualizes the data and saves it to a database. Student knows the principles of the industrial internet and knows the IIoT technologies.

Assessment criteria, excellent (5)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a web-based application, which visualizes the data and saves it to a database. Student can utilize IIoT technologies in the application development.

Assessment methods and criteria

Exam 75 % and exercises 25 %

Qualifications

Network programming
Prommable logic controllers

Further information

The issues of automation technology are internationally similar.

Objective

Student knows how the development in industrial internet and internet of things affects to the manufacturing industry and services.
Student knows how to develop IoT services and utilize cloud computing. Student knows how to send data from industrial processes and devices to IoT services. Student knows the impact of industrial internet of things on sustainable development.

Content

Principles of industrial internet
Cloud services and IoT platforms
Standards and protocols used with industrial internet (OPC UA, MQTT, AMQP)
Web development for IoT

Materials

Information about the materials are in Moodle.

Teaching methods

Contact teaching and independent work.

Student workload

3 cu * 27 h/cu = 81 hours, of which around one third is contact teaching and two thirds independent work.

Evaluation scale

1-5

Assessment criteria, satisfactory (1)

Student knows the basics of industrial internet and cloud services. Student can make a simple program which transmits data from simulated automation system to a cloud service.

Assessment criteria, good (3)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a simple web-based application, which visualizes the data and saves it to a database. Student knows the principles of the industrial internet and knows the IIoT technologies.

Assessment criteria, excellent (5)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a web-based application, which visualizes the data and saves it to a database. Student can utilize IIoT technologies in the application development.

Assessment methods and criteria

Activities including assignment and exam.

Qualifications

Network programming
Prommable logic controllers

Further information

The issues of automation technology are internationally similar.

Objective

Student knows how the development in industrial internet and internet of things affects to the manufacturing industry and services.
Student knows how to develop IoT services and utilize cloud computing. Student knows how to send data from industrial processes and devices to IoT services. Student knows the impact of industrial internet of things on sustainable development.

Content

Principles of industrial internet
Cloud services and IoT platforms
Standards and protocols used with industrial internet (OPC UA, MQTT, AMQP)
Web development for IoT

Materials

Information about the materials are in Moodle.

Teaching methods

Contact teaching and independent work.

Student workload

3 cu * 27 h/cu = 81 hours, of which around one third is contact teaching and two thirds independent work.

Evaluation scale

1-5

Assessment criteria, satisfactory (1)

Student knows the basics of industrial internet and cloud services. Student can make a simple program which transmits data from simulated automation system to a cloud service.

Assessment criteria, good (3)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a simple web-based application, which visualizes the data and saves it to a database. Student knows the principles of the industrial internet and knows the IIoT technologies.

Assessment criteria, excellent (5)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a web-based application, which visualizes the data and saves it to a database. Student can utilize IIoT technologies in the application development.

Assessment methods and criteria

Activities including assignment and exam.

Qualifications

Network programming
Prommable logic controllers

Further information

The issues of automation technology are internationally similar.

Objective

Student knows how the development in industrial internet and internet of things affects to the manufacturing industry and services.
Student knows how to develop IoT services and utilize cloud computing. Student knows how to send data from industrial processes and devices to IoT services. Student knows the impact of industrial internet of things on sustainable development.

Content

Principles of industrial internet
Cloud services and IoT platforms
Standards and protocols used with industrial internet (OPC UA, MQTT, AMQP)
Web development for IoT

Materials

To be announced at the beginning of the course

Teaching methods

Lectures and exercises

Exam schedules

The exam is in the last lesson

Student workload

Lectures 37 %, independent studying 63 %.

Evaluation scale

1-5

Assessment criteria, satisfactory (1)

Student knows the basics of industrial internet and cloud services. Student can make a simple program which transmits data from simulated automation system to a cloud service.

Assessment criteria, good (3)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a simple web-based application, which visualizes the data and saves it to a database. Student knows the principles of the industrial internet and knows the IIoT technologies.

Assessment criteria, excellent (5)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a web-based application, which visualizes the data and saves it to a database. Student can utilize IIoT technologies in the application development.

Assessment methods and criteria

Exam 75 % and exercises 25 %

Qualifications

Network programming
Prommable logic controllers

Further information

The issues of automation technology are internationally similar.

Objective

Student knows how the development in industrial internet and internet of things affects to the manufacturing industry and services.
Student knows how to develop IoT services and utilize cloud computing. Student knows how to send data from industrial processes and devices to IoT services. Student knows the impact of industrial internet of things on sustainable development.

Content

Principles of industrial internet
Cloud services and IoT platforms
Standards and protocols used with industrial internet (OPC UA, MQTT, AMQP)
Web development for IoT

Materials

To be announced at the beginning of the course

Teaching methods

Lectures and exercises

Assessment criteria, satisfactory (1)

Student knows the basics of industrial internet and cloud services. Student can make a simple program which transmits data from simulated automation system to a cloud service.

Assessment criteria, good (3)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a simple web-based application, which visualizes the data and saves it to a database. Student knows the principles of the industrial internet and knows the IIoT technologies.

Assessment criteria, excellent (5)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a web-based application, which visualizes the data and saves it to a database. Student can utilize IIoT technologies in the application development.

Assessment methods and criteria

Exam and exercises

Qualifications

Network programming
Prommable logic controllers

Further information

The issues of automation technology are internationally similar.

Objective

Student knows how the development in industrial internet and internet of things affects to the manufacturing industry and services.
Student knows how to develop IoT services and utilize cloud computing. Student knows how to send data from industrial processes and devices to IoT services. Student knows the impact of industrial internet of things on sustainable development.

Content

Principles of industrial internet
Cloud services and IoT platforms
Standards and protocols used with industrial internet (OPC UA, MQTT, AMQP)
Web development for IoT

Assessment criteria, satisfactory (1)

Student knows the basics of industrial internet and cloud services. Student can make a simple program which transmits data from simulated automation system to a cloud service.

Assessment criteria, good (3)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a simple web-based application, which visualizes the data and saves it to a database. Student knows the principles of the industrial internet and knows the IIoT technologies.

Assessment criteria, excellent (5)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a web-based application, which visualizes the data and saves it to a database. Student can utilize IIoT technologies in the application development.

Qualifications

Network programming
Prommable logic controllers

Further information

The issues of automation technology are internationally similar.

Objective

Student knows how the development in industrial internet and internet of things affects to the manufacturing industry and services.
Student knows how to develop IoT services and utilize cloud computing. Student knows how to send data from industrial processes and devices to IoT services. Student knows the impact of industrial internet of things on sustainable development.

Content

Principles of industrial internet
Cloud services and IoT platforms
Standards and protocols used with industrial internet (OPC UA, MQTT, AMQP)
Web development for IoT

Materials

To be announced at the beginning of the course

Teaching methods

Lectures and exercises

Assessment criteria, satisfactory (1)

Student knows the basics of industrial internet and cloud services. Student can make a simple program which transmits data from simulated automation system to a cloud service.

Assessment criteria, good (3)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a simple web-based application, which visualizes the data and saves it to a database. Student knows the principles of the industrial internet and knows the IIoT technologies.

Assessment criteria, excellent (5)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a web-based application, which visualizes the data and saves it to a database. Student can utilize IIoT technologies in the application development.

Assessment methods and criteria

Exam and exercises

Qualifications

Network programming
Prommable logic controllers

Further information

The issues of automation technology are internationally similar.

Objective

Student knows how the development in industrial internet and internet of things affects to the manufacturing industry and services.
Student knows how to develop IoT services and utilize cloud computing. Student knows how to send data from industrial processes and devices to IoT services. Student knows the impact of industrial internet of things on sustainable development.

Content

Principles of industrial internet
Cloud services and IoT platforms
Standards and protocols used with industrial internet (OPC UA, MQTT, AMQP)
Web development for IoT

Evaluation scale

1-5

Assessment criteria, satisfactory (1)

Student knows the basics of industrial internet and cloud services. Student can make a simple program which transmits data from simulated automation system to a cloud service.

Assessment criteria, good (3)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a simple web-based application, which visualizes the data and saves it to a database. Student knows the principles of the industrial internet and knows the IIoT technologies.

Assessment criteria, excellent (5)

Student can develop application, which sends data from the automation system to the cloud service. Student can make a web-based application, which visualizes the data and saves it to a database. Student can utilize IIoT technologies in the application development.

Qualifications

Network programming
Prommable logic controllers

Further information

The issues of automation technology are internationally similar.