Spidey Sense: Difference between revisions

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* Lotte Hollander: writing report + wiki, graphic design, prototyping
* Lotte Hollander: writing report + wiki, graphic design, prototyping
* Romy Lauwers: writing report + wiki, literature, photoshop
* Romy Lauwers: writing report + wiki, literature, photoshop
* Mark Wijnands: mechanics, control
* Mark Wijnands: mechanics, control, 3D design
* Noor Schroen: programming, electronics
* Noor Schroen: programming, electronics
* Gialesi Notkamp: programming, electronics
* Gialesi Notkamp: programming, electronics

Revision as of 19:09, 10 February 2019

Back to PRE2018 3 Group8

Problem statement and objectives

Aid workers can not always estimate the critical situation of a disaster area well enough, because they do not have enough information to act upon. Victims can be helped quicker if aid workers would be able to operate in small spaces with the right equipment.

Objectives:
The following objects are SMART objectives.

  • The solution should localize the victims of a disaster area
  • The solution should be ready for use
  • The solution should be tiny/small
  • The solution should be adaptable
  • The solution should be strong (enough for mechanical loads)
  • The solution should be autonomous
  • The solution should be user-friendly
  • The solution should be able to function in an unknown and dynamic environment
  • The solution should be durable

Who are the users?

Primary users

Non-profit organisations

Non-profit organisations, e.g. the Red Cross, can give workshops/education about the use of the robot.

Aid Workers

They actually use the robot in the field.

Secondary users

Volunteers

Victims

Tertiary users

Government

Hospitals

What do they require?

Non profit organisations

Aid Workers

  • Working quicker, because the robot is ready for use
  • Own safety
  • More information/data about the situation in critical conditions

Volunteers

  • Safety while trying to search for survivors/victims.

Victims

  • Victims need the medical aid as fast as possible.

Government

  • Lower (medical) costs
  • Less casualties

Hospitals

  • Quicker discharge of patients

USE Aspects

Users

Society

Enterprise

Approach, milestones and deliverables

Approach

To tackle this project, we started with extensive research on the state of the art. This is done by examining the current literature on the subject. These examined papers outline the current state of the problem, solutions to these problems, and their flaws.

After obtaining a better view on the problem at hand, the USE (user, society and enterprise) aspects are analyzed, to determine why this problem is relevant. These three aspects should always be kept in mind during each stage of the project. These aspects may sometimes ask for different solutions to the same problem, so they must be analyzed to determine which aspect should be taken into account more, and compromises must be made. Also different subproblems may ask for different USE aspects, but two solutions from two subproblems may not always be able to be combined, meaning that choices must be made.

After having analyzed the USE aspects, a scenario will be made where the robot shows of its capabilities, and multiple persona’s will also be made who come into contact with the robot.

Then, we will start the production of our own spider robot. As with each project with a tangible deliverable, the robot start off as a sketch. Multiple designs will be made, and the best one will be chosen. Then, the necessary components will be analyzed and subsequently tested. After we know that the different components work, they will be assembled into our final product. After obtaining a finished product it will be tested and evaluated. If improvement is needed, the product will be improved.

During this process, a report will be written in which this whole process is outlined in a more detailed manner, and which also follows our progress. This report will also more finely describe the problem and the solutions.

After all this is done, we are nearly at the end, and a presentation will be prepared and presented, the wiki will be done, and all deliverables will be handed in.

Milestones

  • Decide on subject (06/02/19)
  • Formulate problem statement (06/02/19)
  • Finish literature study
  • Finish designs for product
  • Test sensors
  • Finish assembly of product
  • Present product
  • Finalize the wiki

Deliverables

  • Wiki (report)
  • Final presentation
  • A prototype

Planning

PLANNING
Week 1 Literature study (Gialesi, Lotte, Mark, Romy) Problem statement (Everybody) Define users and user needs (Everybody) Make planning (Noor) Update Wiki (Romy)
Week 2 List of sensors and components (Gialesi, Noor) Scenario/persona's (Lotte) Make designs (Everybody) Analyze USE aspects (Romy)
Week 3 Assembly of product (Gialesi, Lotte, Noor, Mark) Test sensors (Gialesi) Write report (Everybody)
Week 4
Week 5
Week 6 Test prototype (Noor)
Week 7 Improve prototype (Gialesi, Lotte, Noor, Mark) Evaluate Prototype (Mark) Prepare presentation (Lotte)
Week 8
Week 9 Presentation Hand in deliverables

Who's doing what?

  • Lotte Hollander: writing report + wiki, graphic design, prototyping
  • Romy Lauwers: writing report + wiki, literature, photoshop
  • Mark Wijnands: mechanics, control, 3D design
  • Noor Schroen: programming, electronics
  • Gialesi Notkamp: programming, electronics

SotA

Spider Robot and Motion:
[1] This paper looks at certain safe points where the spider robot can place its feet and where not in a plane.
[2] This paper looks at certain points where the spider can and cannot place its feet.
[3] This paper looks at a spider robot that climbs autonomously in pipelines. Could be useful for the small spaces.
[4] This paper is about the capabilities of the spider and studies the foot force and torque distribution of the spider in different conditions and compares the leg configurations in order to minimize the torque effort.
[5] This paper discusses foot designs and fabrication for use with a spider-inspired climbing robot.
[6] This paper is about a four-legged spider robot that learns how to move in its environment and reacts to physical changes.
[7] This article discusses a dragline-forming robot inspired by spiders
[8] This is the site of Robugtix. This company has a small spider robot, which can make smooth, life-like motions. The toy comes equipped with a 3D printed body, 26 motors, and microcontroller board pre-loaded with the Bigfoot™ Inverse Kinematics Engine.
[9] This paper focusses on a spider-imitated robot used for rescue

Relevant Rescue Robots
[10] This paper is about a rescue robot with debris opening function
[11] This paper is about MOIRA the Mobile Inspection robot for Rescue Activities.
[12] This paper is about a robot that can move the debris.
[13] This patent is about an all-terrain rescue and disaster-relief robot.
[14] This paper discusses an aerial search and rescue robot and its application to a specific earthquake.
[15] This paper is about modular, reconfigurable rescue robots.
[16] This article describes a so called WALK-MAN robot in post-earthquake scenario's.
[17] This patent is for an autonomous detection system and method of rescue robot in disaster area for complex environment
[18] This patent is for a full topography intelligence rescue robot with self-balancing objective table
[19] This patent is about an emergency relief goods transporting robot

Disaster Rescue
[20] This patent focusses on a method for priority evaluation for robots under disaster rescue environment
[21] This article is about a challenge that aims to accelerate the development of robots that can help humans, not only with nuclear emergencies but also with fires, floods, earthquakes, chemical spills, and other kinds of natural and man-made disasters.
[22] This patent is about video search and a rescue robot based on ZigBee wireless positioning and search and rescue method

Rescue robot interaction
[23] This paper provides a short tutorial on how robots are currently used in urban search and rescue and discusses some robot-human interaction issues encountered over the past eight years.
[24] This paper talks about non-facial and non-verbal affective expressions for appearance-constrained robots.

Prototypes of a spider robot
[25] This paper is about a high tech spider prototype, mady by reseachers of the Fraunhofer Institute for Manufacturing Engineering and Automation IPA. The prototype will provide emergency responders with an image of the situation on the ground, along with any data about poisonous substances. Future plans envision its use as an exploratory tool in environments that are too hazardous for humans, or too difficult to get to. Furthermore, the prototype is very cheap to produce.
[26] This site has an instruction guide to print 3D parts of a spider robot with four legs. It is possible to place an arduino in the middle of the design.
[27] This patent is for a novel rescue robot that can efficiently walk in a complex post-disaster area through a design of a spider-like structure

Robots with interesting factors
[28] This robot is portable and foldable and quickly carried in a backpack to a site where inspection, exploration, search and rescue, and other tasks are required to performed.