PRE2016 2 Groep1: Difference between revisions
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= Week 3 = | = Week 3 = | ||
In week 3 every group started with their individual tasks (as described by the Gantt-chart in week 2). A complete list was made of the different contaminants we would like to investigate and how to do this using different sensors and how they could be applied. For the simulating of the swarm the Matlab application 'Multi-robot simulation' is investigated to check its functions and compatibility with our project. If these results are positive this program can be used to design our system. For the environment a map was made using a picture of the harbor of Rotterdam. A software was used to convert this into a black and white map we can use for our simulation. The resolution of this map is going to be enhanced by reducing the size of the map we use. Our contact with the external companies has not yet given results, since these contacts had either no time or did not respond at all. | In week 3 every group started with their individual tasks (as described by the Gantt-chart in week 2). A complete list was made of the different contaminants we would like to investigate and how to do this using different sensors and how they could be applied. For the simulating of the swarm the Matlab application 'Multi-robot simulation' is investigated to check its functions and compatibility with our project. If these results are positive this program can be used to design our system. For the environment a map was made using a picture of the harbor of Rotterdam. A software was used to convert this into a black and white map we can use for our simulation. The resolution of this map is going to be enhanced by reducing the size of the map we use. Our contact with the external companies has not yet given results, since these contacts had either no time or did not respond at all. | ||
== Detection Methods == | |||
A list was made of all different contaminants we could look at for our system. After this methods were found to detect each of these. Following this list, combined with feedback of the users, a final choice can be made for which detection methods to incorporate in the final design. | |||
=== Wood === | |||
This was explained by the sea-harbor police as a problem for them. The first option that was looked into was a Gelsight sensor, this sensor can determine what material it is pressed against by comparing its surface to a database. This would however need a drone to have already found the object in the first place. Because of this it would be better to combine cameras with recognition software to find floating objects, regardless of material. | |||
=== Oxygen === | |||
For oxygen the most practical detection method for our system would be a dissolved oxygen sensor. For the amount of oxygen which can be dissolved in water is influenced by the factors of temperature, pressure and salinity. Because of this a dissolved oxygen sensor also has a thermometer and a barometer. | |||
=== Salinity === | |||
The salinity is the amount of salts and similar materials in water. This is directly related to its conductivity. Because of this an electric conductivity meter can be used. | |||
=== pH-value === | |||
The pH-value of water is a good indication of water pollution. Not only do some substances have a very low or high pH-value themselves, thus altering the value of the water when added. A low pH-value also allows (heavy) metals to dissolve more easily, making them mobile. For the pH-value a pH-sensor can be used, as the name implies. | |||
=== Oil spills === | |||
Although a lot of pollutions can be seen visually by a person, for a drone this can be more difficult. A methods that could be applied to our system for the detection of oil can be using uv-fluorescence. This is based around oil reflecting uv-light, allowing it to be detected. | |||
== Creation of 3D-space == | |||
== Swarm system == | |||
[[file:notes 1-12.pdf]] | [[file:notes 1-12.pdf]] | ||
Revision as of 15:28, 5 December 2016
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You can click the following link for more background information on the course and the project. [1] This link leads to the studieguide that was placed on oase. Week 1The goal of the first week was to decide on a subject for our project and what we were planning to do with this. This started on Monday with the first lecture, where we got more information about the course itself. After this we started brainstorming about different possible ideas to look into. A few examples of the things we looked at were space-exploration, robotic prosthetic and automating hazardous professions like firefighting. In the end we decided on swarm technology. We did still have to specify this so after the meeting we individually looked into some different applications of swarm technology. In the second meeting (17-11) we decided on a final subject: using swarm technology to observe the environment, focused on water like harbors and rivers. Here we want to test the quality of the water by looking at Chemicals, temperature, pH and metals. We decided on making a simulation of the system which can eventually be expanded. The next step was to figure out exactly what we need to make the simulation as realistic as possible, the USE-aspects and how we are going to approach the goal we set for ourselves. Our next meeting (19-11) was focused on combining the results we made throughout the week into a presentation that was to be given the following monday. Week 2
Week 3In week 3 every group started with their individual tasks (as described by the Gantt-chart in week 2). A complete list was made of the different contaminants we would like to investigate and how to do this using different sensors and how they could be applied. For the simulating of the swarm the Matlab application 'Multi-robot simulation' is investigated to check its functions and compatibility with our project. If these results are positive this program can be used to design our system. For the environment a map was made using a picture of the harbor of Rotterdam. A software was used to convert this into a black and white map we can use for our simulation. The resolution of this map is going to be enhanced by reducing the size of the map we use. Our contact with the external companies has not yet given results, since these contacts had either no time or did not respond at all. Detection MethodsA list was made of all different contaminants we could look at for our system. After this methods were found to detect each of these. Following this list, combined with feedback of the users, a final choice can be made for which detection methods to incorporate in the final design. WoodThis was explained by the sea-harbor police as a problem for them. The first option that was looked into was a Gelsight sensor, this sensor can determine what material it is pressed against by comparing its surface to a database. This would however need a drone to have already found the object in the first place. Because of this it would be better to combine cameras with recognition software to find floating objects, regardless of material. OxygenFor oxygen the most practical detection method for our system would be a dissolved oxygen sensor. For the amount of oxygen which can be dissolved in water is influenced by the factors of temperature, pressure and salinity. Because of this a dissolved oxygen sensor also has a thermometer and a barometer. SalinityThe salinity is the amount of salts and similar materials in water. This is directly related to its conductivity. Because of this an electric conductivity meter can be used. pH-valueThe pH-value of water is a good indication of water pollution. Not only do some substances have a very low or high pH-value themselves, thus altering the value of the water when added. A low pH-value also allows (heavy) metals to dissolve more easily, making them mobile. For the pH-value a pH-sensor can be used, as the name implies. Oil spillsAlthough a lot of pollutions can be seen visually by a person, for a drone this can be more difficult. A methods that could be applied to our system for the detection of oil can be using uv-fluorescence. This is based around oil reflecting uv-light, allowing it to be detected. Creation of 3D-spaceSwarm systemThis link standing below is a link to our Dropbox files for this week. There all the files we worked on can be seen to clarify anything missing from the description above. [week 3[2]] Week 4This link standing below is a link to our Dropbox files for this week. There all the files we worked on can be seen to clarify anything missing from the description above. [week 4[3]] |
