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Open Roberta

From Wikipedia, the free encyclopedia
Open Roberta
Paradigmevent-driven, imperative
Designed byBeate Jost, Reinhard Budde, Thorsten Leimbach, Achim Kapusta
DeveloperFraunhofer IAIS, Media Engineering Department
First appeared2013; 11 years ago (2013) (test) 2014; 10 years ago (2014) (official)
Stable release
5.2.0 / May 10, 2023; 17 months ago (2023-05-10)
Typing disciplinedynamic
Implementation languageJava, JavaScript, HTML (NEPO)
OSWindows, Linux, iOS
License Apache License 2
Websitewww.open-roberta.org
Influenced by
Scratch, Blockly

Open Roberta is a project within the German education initiative "Roberta – Learning with robots", initiated by Fraunhofer IAIS, which is an institute belonging to the Fraunhofer Society. With Open Roberta Fraunhofer IAIS is looking to encourage children to code by using robots such as Lego Mindstorms, and other programmable hardware systems such as Arduino, BBC micro:bit, and the Calliope mini. The Cloud-approach of the Open Roberta Lab is intended to simplify programming concepts and make it easier for teachers and schools to teach how to code.[1] Open Roberta is free and does not require any installation. The project was initially founded with €1m by Google.org.[2][3] Users from up to 120 countries now access the platform.

Open Roberta Lab

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Open Roberta Lab.

Open Roberta Lab is cloud-based programming environment and is the user-facing middleware in a chain of software and firmware bits that make a robot work in a classroom environment.[4] This environment allows children and young people with no technical pre-knowledge to program a LEGO MINDSTORMS[5] EV3 and NXT robot, as well as the Arduino based robot Bot'n Roll ONE A,[6] the BBC micro:bit,[7] and the Calliope mini.[8] As of the release 2.3.0, the microboard B-O-B-3 and as of release 3.0 the microboards Arduino Uno, Arduino Nano and Arduino Mega can also be programmed using Open Roberta. There is a variety of different program blocks available to program the motors, sensors, and the EV3 brick.[9] Open Roberta Lab uses the approach of visual programming. This approach makes it easier, especially for beginners with no experience, to learn how to code. As a cloud based programming environment no installation is needed and any operating system (Mac OS, Windows, Linux) and computer hardware device may be used.[10][11] One of the advantages of Open Roberta Lab is that it can be used with any device (PC, tablet, smartphone); only a web browser is needed. The Lab can be used without registration, and no user account is needed. As of the release 2.2.1, the Linux-based operating system EV3dev is officially supported for the LEGO MINDSTORMS EV3 robot. Open Roberta Lab is available in the following languages: Catalan, Czech, Danish, Dutch, English, Finnish, French, German, Italian, Polish, Portuguese, Russian, Spanish and Turkish.

Open source community

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The programming platform Open Roberta Lab is open source developed.[12] Both the software as well as the open source development tools are available on a server of Fraunhofer Society. The development team at Fraunhofer works together with teachers and education experts from the Roberta network. Therefore, also universities and students are involved in the development. It should address especially female students - the guiding principle of the Roberta project.

Programming language NEPO®

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NEPO program Hello World.

NEPO is a free open source meta programming language that can be used by students, scholars, teachers, and other interested persons within the Open Roberta Lab. NEPO translates to New Easy Programming Online (or simply OPEN read backwards). NEPO is the name of the graphical programming language and its coupled hardware connection layer. NEPO uses the freely available Blockly library. In addition within NEPO there are additional functionalities and improvements which have been adapted for Open Roberta. The programming paradigm of NEPO is inspired by Scratch, which was developed by the Massachusetts Institute of Technology. A NEPO block always represents and encapsulates a certain robot functionality. A blocks feature set can easily be recognized through the associated block category, for example »sensors«. Programming with NEPO follows a simple principle. The blocks are interconnected and will be executed by the robot according to their order. This principle is called "sequential operation."

NEPO block categories

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All available blocks are listed and categorized as the Action, Sensors, Control, Logic, Math, Text, Colours, Variables, Functions, and Messages as shown in the table below.

Category Notes    Category Notes
  Action Includes blocks for the robot to be performed directly.      Text Includes blocks to write strings on the robot display.
  Sensors Contains blocks for all standard sensors of the EV3 system.   Colours Standard colour blocks to compare sensor inputs.
  Control Includes blocks for the program sequence control. The category includes the following blocks: If .. do, If .. do .. else, repeat indefinitely, repeat .. times, wait .. ms, wait until ..   Variables Local and global variables can be defined.
  Logic With the »logic« blocks, conditions can be created. With this condition you can interrelate states, values, and events with each other.   Functions Functions with input and output parameters can be defined.
  Math Mathematical operators and parameter blocks.   Messages Includes blocks to send and receive bluetooth messages.
  List Includes blocks to create a list and to search or sort list elements.   program-start Each program starts with this block. This block is always available in the workspace.
  Neuronal Networks Includes blocks for coding a neuronal network.

NEPO input / output connector

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NEPO typ check input connectors.

Depending on the block different values can be passed to a block. The type of the value can be identified by the colored compounds (called including »connectors«) of a block. In the chapter »block category« you can see the different values a block may have. Only if the colors of the input and the output connector match, these blocks can be connected.

A block may optionally also pass a value to another block. These blocks have colored output connectors. Only if the colors of the input and the output connector are the same, these blocks can be connected.

NEPO typ check output connectors.

In total there are six input and output types within NEPO. These types can have the following values:

  • Logical value (light blue)
  • Number (dark Blue)
  • String / Text (green)
  • Colour (yellow)
  • List (purple)
  • Connection (pink)

Artificial neural networks

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Integrating artificial neural networks into the Open Roberta Lab.
Integrating artificial neural networks into the Open Roberta Lab.

Since August 2022, the Open Roberta Lab offers the functionality to program artificial neural networks. With this integration, the topic "Artificial Intelligence" was integrated into the Open Roberta Lab. This is done along the framework curriculum for computer science in North Rhine-Westphalia. The project is funded by the Ministry for School and Education of North Rhine-Westphalia. The graphical integration enables a low-threshold access. The feature makes AI algorithms intuitively experienceable and understandable through graphical programming. The goal is for students from grades 5 and 6 to understand what an artificial neural network is and how it works. They also learn to program themselves, for example to enable a robot to move independently in its environment.

The structure and functioning of simple neural networks can be understood step by step. The networks programmed by the students can be tested directly in the 2D simulation provided in the Open Roberta Lab, so that the children receive immediate feedback. Once the basics are understood, students can train the artificial neural network. A robot can thus be "taught" to avoid obstacles, as vacuum cleaner robots do, for example.

Open Roberta Simulator

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Open Roberta 2D simulation of a wheeled robot.

Since version beta 1.3.0 the Open Roberta Lab also offers a simulation environment. This is a simulation of a two-dimensional robot model equipped with two wheels (differential drive). To program the simulated robot also the programming language NEPO may be used. The simulated 2D model includes the simulation of an ultrasonic sensor, a touch sensor, a color sensor and the display of an LED. In addition, different environments can be chosen. Since version beta 1.4.0 NEPO blocks can be used without any changes for the 2D-Simulation and the real robot.

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As of release 2.3.0, the "Gallery" is available, allowing users to share their own programs with everyone else. Logged-in users with a verified account can share their programs by clicking "edit" in the menu bar, followed by a click on the menu point "my programs." In the following overview of the programs saved online, they then just have to click on the gallery-icon on the right-hand side.

In order to load a program off the Gallery, users – logged in or not – double-click on the chosen program and are then able to view, change or download its content.

Integrated Systems

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System Programming Language Simulation Transfer Compiler
Arduino C/C++ no USB arduino-builder
micro:bit MicroPython yes USB
micro:bit V2 MicroPython yes USB
Bionic Flower C/C++ no USB
Bionics Kit C/C++ no USB
BOB3 C/C++ no USB, Bluetooth C/C++
Bot'n'Roll C/C++ no USB arduino-builder
CalliBot C yes USB, Bluetooth
Calliope mini C/C++ yes USB, Bluetooth
Edison MicroPython no Audio
Lego Mindstorms NXT NXC yes USB NXC
Lego Mindstroms EV3 C, Java, Python yes USB, WLan arm-linux, Java
Lego WeDo Token basiert no Bluetooth Lego Original
mBot C++ yes USB arduino-builder
mBot 2 Python no USB arduino-builder
NAO Python yes WLan, Ethernet
ROB3RTA C/C++ yes USB, Bluetooth C/C++
senseBox C/C++ no USB arduino-builder
Thymio Aseba yes USB, Bluetooth Aseba

History

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Open Roberta is a technological extension of the "Roberta concept". Roberta (short for: "Roberta – Learning with robots") is a Fraunhofer education initiative founded in 2002 by the Germany Ministry of Education and Research. Since 2002 over 350,000 students have participated in Roberta courses.

Awards

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Open Roberta was awarded the "Bundessieger 2015" at the challenge "Germany Land of Ideas" in the education category.[13] In 2016, Open Roberta won the bitkom award "d-elina" in the professional category.[14]

References

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  1. ^ "Open Roberta – a Web Based Approach to Visually Program Real Educational Robots". Tidsskrift. Retrieved 29 December 2019.
  2. ^ Berkler, Katrin. "Pressemitteilung vom 24.03.2015". Fraunhofer. Retrieved 29 December 2019.
  3. ^ "'Open Roberta' – Fraunhofer, Google und LEGO Education lassen die Roboter los". Google Product Blog. 4 November 2014. Retrieved 29 December 2019.
  4. ^ Williams, Elliot (11 May 2016). "Open Robots with Open Roberta". Hackaday. Retrieved 29 December 2019.
  5. ^ Willner-Giwerc, Sara (10 September 2015). "Open Roberta: a review". Lego Engineering. Retrieved 29 December 2019.
  6. ^ "Bot'n Roll ONE a Robot".
  7. ^ "The Micro:bit Foundation is a global non-profit organisation making invention with technology fun for everyone!". microbit.org. Retrieved 2016-11-16.
  8. ^ "CALLIOPE | Home". calliope.cc. Retrieved 2016-11-16.
  9. ^ Geek in Sydney
  10. ^ "Open Roberta Lab" Archived 2015-06-25 at the Wayback Machine
  11. ^ Jost, B., Ketterl, M., Budde, R., Leimbach, T. Graphical Programming Environments for Educational Robots: Open Roberta – Yet another One?, in IEEE International Symposium on Multimedia (ISM), December 2014
  12. ^ Sawers, Paul (4 November 2014). "With Open Roberta, Google wants to help German school kids learn to program with robots". The Next Web. Retrieved 29 December 2019.
  13. ^ Germany Land of Ideas Archived 2015-12-08 at the Wayback Machine
  14. ^ Streim, Andreas. "Bitkom zeichnet beste E-Learning-Projekte aus". bitkom. Retrieved 29 December 2019.
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