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===Energy===
===Energy===
The ocean offers several alternative options for energy generation. When a robot can use it's own energy on the sea, it is more autonomous.
The ocean offers several alternative options for energy generation.<ref name="Ocean Energy Europe">[http://www.oceanenergy-europe.eu/index.php/association/technologies Ocean Energy Europe]</ref> When a robot can use it's own energy on the sea, it is more autonomous.
Options for Alternative ocean energy:
Options for Alternative ocean energy:
*Tidal energy: generates energy from the currents caused by the tides. The flow makes a rotor or foil spin and the mechanical moition is then converted to electricity. Tidal energy is in development and taking steps to commercial viability.
*Tidal energy: generates energy from the currents caused by the tides. The flow makes a rotor or foil spin and the mechanical moition is then converted to electricity. Tidal energy is in development and taking steps to commercial viability.
Line 250: Line 250:
*Tidal Range: Uses the difference in sea level with the tides to generate electricity. Fills a barrier at high tide and discharges the water from one side to the other at low tide. It is essentially the same technology as with conventional hydropower.
*Tidal Range: Uses the difference in sea level with the tides to generate electricity. Fills a barrier at high tide and discharges the water from one side to the other at low tide. It is essentially the same technology as with conventional hydropower.
*Ocean thermal energy conversion:is a very consistent energy source and provides so called base-load power. The temperature differences between deep cold waters and shallow warm and tropical waters is exploited to run a heat engine.
*Ocean thermal energy conversion:is a very consistent energy source and provides so called base-load power. The temperature differences between deep cold waters and shallow warm and tropical waters is exploited to run a heat engine.
source Ocean energy europe http://www.oceanenergy-europe.eu/index.php/association/technologies


==Proposed design==
==Proposed design==

Revision as of 08:30, 23 May 2016


HASP logo v0.1.png

Group members

Introduction

Abstract

Problem statement

The world needs to produce at least 50% more food to feed 9 billion people by 2050. But climate change could cut crop yields by more than 25%.[1] With this in mind we need to look for novel solutions to the problem of insufficient food production. This solution will need to take the interests of users, society, and enterprise into account. Moreover, this solution needs to surpass the state of the art by employing cutting-edge technology.

Motivation

Nutrition is vital to sustaining life, and food security is important for political stability and human welfare. We want to address the problem of food availability due to its relevance: continuing population and consumption growth will mean that the global demand for food will increase for at least another 40 years.[2]

Agriculture is an integral part of the European economy and society. It provides the basis for food, feed and non-food products to meet the demands of consumers and a wide range of industries.[3] By designing a solution to the agricultural challenge we will need to take into account the needs of users: like consumers of food, society: the ecological impacts of our solution, and enterprise: the solution needs to be competitive in order to gain an economical advantage.

The agricultural industry is ever advancing, not only is the biological aspect of farming being researched, there are also improvements in automation,[4] and we want to explore the automation of this industry. We want to develop a solution that allows for automation of food production beyond the state of the art, moreover the solution needs to be scalable.

Mariculture

Representation of a sea farm

Mariculture is a specialized branch of aquaculture involving the cultivation of marine organisms for food and other products in the open ocean, an enclosed section of the ocean, or in tanks, ponds or raceways which are filled with seawater. An example of the latter is the farming of marine fish, including finfish and shellfish like prawns, or oysters and seaweed in saltwater ponds.[5]

In this section we will explore mariculture, and explain why we chose it as a solution to the problem previously stated. Mariculture encompasses a wide range of organisms, from the cultivation of water-based plants to the breeding of aquatic animals. For this project we will focus on the cultivation of aquatic plants, and in particular types of seaweed.

Commonly cultivated seaweed species

  • The total seaweed production features a lot of brown kelps. These weeds grow in cold water zones, they are long and have a leathery structure. They must be harvested before the water temperature rises to 21 degrees, otherwise the kelps will rot. Kombu (Laminaria Japonica) is used a lot in Japanese recipies for soups, as dried snacks, or in salads. Kombu is a dietary fiber and contains high levels of iodine. In China, 50% of the Laminaria production is meant for industrial purposes for its iodine, algin and mannitol. Due to this, laminaria are considered as one of the best renewable resources and it makes up for a major part of the maricultural sector. Japan has made effort to increase the production but due to its labour intensitive nature, the market is not expected to expand notably.[6] Wakame (Undaria) is the type of kelp you will find in your misosoup. With a subtle sweet flavour and satin-like texture it is most suitable for human consumption. The weed is a rich source of omega-3 and helps burn fatty tissue. However, it is also in the top 100 of worst invasive species in cold waters, which is partly caused by aquaculture.[7]
  • Gelidium amansii and Pterocladia are valuable red algae that can be found at shallow coasts. They can be used in salads and to make agar, a jelly-like substance that can be used for microbiological research and various industrial purposes.[8] They have been cultured in Korea since the last century, but always on a small scale. There have been various attempts to farm the algae at sea, but the slow growth rate and required non-contaminated waters made it unattractive for commercial cultivation.[9]
  • Nori or Zicai (Porphyra) are most famous for composing the sushi wraps. The red algae grow in cold and shallow waters in the intertidal zone. After growing in the sea for 50 days, the weeds can be harvested every 10-15 days. The Nori market is stable, the demand is not expected to grow or shrink in the coming years. In Japan, the annual production is valued at 1 billion US dollars.[10]

Mariculture as a solution

Environment

Dead zones

Dead zones in oceans around the world.

Ocean dead zones are areas with low oxygen levels and hardly any marine life. These areas are caused by agriculture fertilizers that increase the level of nitrogen and phosphorus, also known as eutriphication. The result is a rapid increase in phytoplankton, because they are 'build' from phosphorus and nitrogen. These algal blooms cause deadzones. The number of deadzones is increasing. As a result, the fertility of the marine life drops dramatically, and in more extreme cases, fish fall unconcious and then suffocate. Slow moving creatures on the seafloor are unable to escape. Seaweed is capable of uptaking both nitrogen and phosphorus and replacing it with oxygen. For this reason seaweed is also cultivated around fishfarms. Seaweed would be a cheap although perhaps slow solution in the reviving of dead zones.[11]

Climate

Seaweed can assimilate a lot of CO2 about 30 to 60 times the rate of land plants. But this will not solve the CO2-problem, because the CO2 will be released when the seaweed will be consumed. Seaweed only contributes indirectly to a better milieu. Because of the seaweed farms less forests will disappear for farmlands. This forest contributes to a net CO2 storage. Seaweed can also be used for the production of biomethane and electricity. So the unsustainable fuels can be replaced, this results in less CO2 pollution.

Locations

To determine the best location for a sea-farm we have to take into account several aspects. The temperature of the seawater should be the right temperature for seaweed. For example the best temperature for growing Eucheuma is 20-25 °Celsius, but there are also species that can grow in water of 10 °Celsius. So seaweed can grow in almost every ocean. The depth of the sea does not matter for the seaweed of farm, because we will only use species that grow from the surface downwards. But for the farm itself the depth does matter. Anchoring the farm is easier in a shallow area in the ocean. Commonly these areas are near the coast, an advantage of sea-farms which are near the costs is that the transport from farm to the secondary users is cheaper. Also building and maintaining the farm is easier if it is closer to the mainland. The dead zones are also located near the seashore, so the dead zones are an extra motivation of locating the sea-farms there. A disadvantage are the shipping routes that are located in these areas. Thankfully, these routes are taken by most commercial ships. This leaves open spots near the coast where there are no passing ships and where the seaweedfarms could be located. Important shipping routes at the Dutch coast [1] With the sealevels rising due to climate change, and the seafarm's habit breaking waves, it would be beneficial to locate the farm nearby a shore that is threatend by rising sea levels.

Nutrition

From a nutritional standpoint, the main properties of seaweeds that distinguish them from higher plants are their high mineral and dietary fibre contents. The high iron and magnesium contents are of particular nutritional interest due to their metabolic or functional properties. In comparison with other sources of fibres, seaweeds contain a high proportion of soluble fibres, which exhibit original fermentation patterns in the large intestine. Red seaweeds have a high protein content, comparable to that of high-protein vegetables. Available data suggest that they have a unique amino acid pattern, complementary to that of most terrestrial vegetables.[12] Edible brown and red seaweeds could be used as a food supplement to help meet the recommended daily adult intakes of some macrominerals and trace elements.[13]

There might be some hesitance in the use of seaweed for human nutrition, but the seaweeds which are used as biological filters and food material for farmed animals could easily be included in the human food value chain by this route.[14][15]

As seaweed accumulates important substances from the surrounding water, it does not only accumulate the desired minerals and trace metals but it also accumulates undesirable metals and heavy metals from the surrounding environment.[16] This can be exploited, and seaweed can be used as a biofilter, but if the goal is nutrition it is important to not let seaweed grow in polluted water.

Seaweeds are known for their richness in polysaccharides, minerals and certain vitamins,[17] but they also contain bioactive substances like polysaccharides, proteins, lipids and polyphenols, with antibacterial, antiviral and anti-fungal properties, as well as many others.[18] This gives seaweed great potential as a supplement in functional food or for the extraction of compounds. Proteins, peptides and amino acids from seaweed have shown positive bioactive effects in the treatment of diabetes and cancer, and the prevention of vascular diseases. The amino acid profile of some seaweed species is similar to that of animal foods. Extracts of valuable amino acids for feed supplement could be of potential because essential amino acids cannot be replaced by other compounds.[16]

State of the art

Benefits and drawbacks

Benefits

  • Income, employment and foreign exchange (import/export).
  • Pond-farms can make use of otherwise infertile and underutilized land.
  • Large-scale farms influence coastal water movement, causing enhanced sedimentation and better protection of the coastal areas from erosion.
  • Introduction of seaweed culture rafts, ropes, anchors, etc. can increase the surface area of substrate, which may enhance production of other marine organisms in a similar way to what artificial reefs have been shown to do.
  • Seaweed culture mostly relies on a natural nutrient supply.
  • Seaweed farms offer shelter for other animals, increasing the biodiversity.
  • The area below seaweed farms can be used for invertebrate farming such as sea cucumbers.
  • Seaweed farms may be placed further offshore to better utilize offshore resources.

Drawbacks

  • Conflicts with other users of the coastal zone.
  • Concerns over potential environmental impacts.
  • Large surface area required for viable seaweed culture.
  • Site preparation may involve removal of native animals, plants and destroying the natural environment (e.g. removing rocks) which may damage the local ecosystem.
  • Routine management can result in damage through trampling and accidental damage of the local ecosystem.
  • Physical shading of an area can occur. The effects of this have not been well-studied.
  • Due to the large surface area required, the visual impact can be a strong argument against seaweed farms, especially in coastal areas.
  • Intensive farming may require additional fertilization. This has yet unknown effects on the local ecological system.
  • Large farms and intensive farming may cause deceases to spread more rapidly, causing production loss and other negative effects for the ecology.
  • Intensive farming may reduce the nutrient levels of coastal waters, making it harder for other organisms to survive.

Types of farms

Anchored

Drifting

Tasks to be carried out on farms

Primary tasks

  • Seeding
  • Cleaning
  • Harvesting

Secondary tasks

  • Checking the quality of the plants
  • Removing corrupt plants
  • Pruning

Stakeholders

  • Why? => Provide a feasible feedback
  • Users: Livestock farmers (veevoer), Foodbuyers
  • Enterprise: Seafarmers
  • Society: Reduces the shortage of food


User

Seaweed farmers.

Drawback: Introduction of our system on the mariculture market could cost the jobs of the few brave seaweed farmers we have today. These farmers operate on a small scale on a small market and would be easily competed out. To prevent this, our systems user group is are the already existing seaweed farmers that want to expand their business, and the more industrialized farmers in Asia.

The users: The first users of the farming-robots are the farm-owners. They would not have employees anymore, but they would have robots. The farm-owners would use the robots to set and harvest the seaweed. The secondary users are the store-owners who sell the seaweed. The production costs are lower for product that are made with autonomic robots, so the store-owners can make more profit. Also the food industry is a secondary user which use the seaweed to make other food. The third users are the people who would eat the seaweed.

Society

Seaweed farming has several advantages for the society, but compared to normal food industry it has not the main disadvantages of (land) agriculture. The advantages of mariculture compared to normal agriculture are: there is enough space for a sea-farm. Deforestation to make more space is not necessary for mariculture. Sea-farms do not cause soil salinity and sea-farms do not need a crop rotation or a yearly greenfield land because the ocean flow serves enough nutrition to farm continue. An advantage of sea-farming is that it will benefit the ocean’s biosphere. The areas where fish cannot live , the dead zones, will disappear. The robots could also check the state of the ocean.

Enterprise

It becomes harder and harder to feed the growing population with only agriculture. A good solution for this is using the oceans for food production. Sea-farming is the future. Autonomic robots are also the future. A combination of these two aspect is interesting for companies. The production is relative cheap compared to agriculture. And because in the future there might be food shortage, so new ways of food production are necessary. And if the farms are located in international waters the farmers do not comply to a lot of rules, thus food production will be easier.

Maritime robotics

In this section we will give an overview of maritime robots and their relevant technologies.

Types of robots

Maritime robots can be classified into several categories:

  • Buoy: this robot floats at one spot on the surface. It is mainly used for acquiring data by using sensors attach to the buoy. It can function as an energy generator by using solar panels, also, it can be used as a relay station for communications by attaching a satellite dish.
  • Traveler: this robot can actively move across the water's surface by using some way of propulsion. It can be similar to the sensor buoy in its functions.
  • Underwater Airplane: similar to an airplane, only instead of like flying through the air it moves through water according to the same principles of fluid dynamics. Can be tricky to maneuver because it cannot stop as quickly as other types of robots. This is one of the fastest underwater robots.
  • Diving Box: this robot can move in any direction and float in midwater. However, it is very energy inefficient. Moves up and down based on the principles of buoyancy.
  • Etcetera: robots that don't belong to the other categories.

Locomotion

A passive ocean drifter and a high-speed jet-propelled vessel.
  • Jet propulsion — water is taken in and propelled out at high speed, using a directed nozzle makes this very maneuverable.
  • Ocean current — passively drifting along the ocean current.
  • Propeller — a classic ship's screw to propel forwards and backwards.
  • Undulation — moving the body like a fish does.
  • Wind — using the power of the wind to sail.

Sensing

Sonar can be used for bathymetry, measuring the depth of the ocean floor.
  • Acoustic Doppler current profiler — measures the speed and direction of ocean currents using the principle of “Doppler shift”.
  • Camera — for visual data, has a limited range.
  • Conductivity — together with temperature and depth information, a good estimate of the salinity may be determined.
  • GPS — find the position, only works above the surface of the water.
  • Hydrophone — listen for sounds in the water.
  • Oxygen — determine the oxygen levels of the water.
  • Pressure — determine the depth the robot is at.
  • Semipermeable membrane density — a passive sampling device used to monitor trace levels of organic contaminants. When placed in an aquatic environment, SPMDs accumulate hydrophobic organic compounds, such as polychlorinated biphenyls (PCBs), polyaromatic hydrocarbons (PAHs), and organochlorine pesticides from the surrounding waters.
  • Sonar — is used to find and identify objects in water. It is also used to determine water depth (bathymetry. May disturb marine life.
  • Temperature — determine the temperature of the water.
  • pH — determine the acidity of the water.

Communication

To allow an offshore farm to communicate with a land-based control station (or transmit data between the users/administrators and the farm) there are numerous conventional methods to employ. For instance satellite communication can be used to transmit and receive data. So for our sea-based machines to communicate they would need to have a part that is not submerged, or they would be required to surface to transmit data. We want to employ machines that can communicate while submerged, therefore we need to find a way to transmit data underwater.

There are two ways to transmit signals under water, using wired technology or wireless technology. A wired solution would require an umbilical cord or tether between two communicating nodes or hosts. This wired solution is quite reliable, and obvious if the device that needs to send or receive data needs to be tethered for other reasons such as the supply of power or for anchoring purposes. However, this wired solution has its drawbacks if a device does not need to be tethered — a tether could hinder its freedom of movement — or if the distance to communicate over is quite large. For our project, we want to make use of wireless communication.

Radio waves travel poorly through water, also, the propagation of radio waves gets worse at higher frequencies. So wireless communication using the radio waves — the conventional method above water— is not feasible for our farm. Further down the EM spectrum we will find visible light that could be used for sending optical signals. Optical wireless underwater communication is being researched.[19] But optical waves are affected by scattering. Moreover, transmission of optical signals requires high precision in pointing the narrow laser beams.

Conventionally underwater communications are realized by using acoustic waves. Acoustic wave technology has been in development since the end of World War II. Underwater networking, using a modern network protocol layer stack has also been researched.[20] One aspect to keep in mind when using acoustic communications is that it could disturb marine life,[21] this is a drawback which should be taken into account when deploying an ocean farm.

Energy

The ocean offers several alternative options for energy generation.[22] When a robot can use it's own energy on the sea, it is more autonomous. Options for Alternative ocean energy:

  • Tidal energy: generates energy from the currents caused by the tides. The flow makes a rotor or foil spin and the mechanical moition is then converted to electricity. Tidal energy is in development and taking steps to commercial viability.
  • Wave energy: generates electricity from the height difference in waves. Wave energy is well developped and applicable in many different settings.
  • Salinity gradient: fresh water and salt water mix at the mouts of rivers, where energy can be harnessed from the osmosis process. This technology is in an early development stage with small pilots taking place in Norway and the Netherlands. It is one of the largest renewable energy resources that has not yet been exploited.
  • Tidal Range: Uses the difference in sea level with the tides to generate electricity. Fills a barrier at high tide and discharges the water from one side to the other at low tide. It is essentially the same technology as with conventional hydropower.
  • Ocean thermal energy conversion:is a very consistent energy source and provides so called base-load power. The temperature differences between deep cold waters and shallow warm and tropical waters is exploited to run a heat engine.

Proposed design

Description

Standard Japanese Laminaria farm.
  • Location Our own Dutch North Sea might just be to place to be. With an average temperature of 12 degrees[2], a former deadzone that is struggling with pollution from the many estuaries, and with a country that has always struggled with living beneath a rising sealevel, the seaweed farm has a lot to offer. When we also consider the busy shipping routes in the North Sea, Zeeland would be the most suitable area.
  • Farmed type of seaweed The HASP will farm the Laminaria seaweed species. Because of the high demand for it can not be fulfilled with the current techniques, and because it has a low impact on the enviroment.
  • System DesignThe design of our system will be largely modelled after the traditional seaweed farms. The base station will be placed in the middle, so that the robot can reach every corner of the farm while it has to return to charge.

distance between lines

Automation

Seeding

Like at normal seafarming, the young seedlings will first be grown at land in a greenhouse in the summer, when the water is hot. Mid-November, when they have grown 10-15 cm, they need to be planted at the seafarm. The seedlings are attached to the vertical lines to grow out, with the upper plants receving more sunlight than the lower ones. Can one of our robots attcach the seeds to the ropes?

Control and hygiene

There are several diseases that could affect the seaweed, caused by bacteria or by the enviroment. These diseases can be recognized visually and envirmental factors can be measured. Sensors would be needed for: illumination (too much or too little light causes rot), fres/salt water level and pollution. All diseases require different treatments, for which we have to think of automated solutions. Harm done by water grazers like fish can be minimized by placing the farm in deep waters, away from the coastal fish and the creatures on the seafloor.

Harvesting

Harvesting can be started in April. The plant grows faster in winter and slower in summer, with a rate of 1.1 cm per day in May. Making up for 2.5 meters a year. The plant can regenerate when it's been trimmed, but will grow slower. The normal age with this practice does not exceed 4 years.

Drying

It seems very inefficient to dry the seaweed in the open sea, it takes a lot of space and when one wave flushes over it, all the drying will have been for nothing. For that reason, seaweed must be taken to the mainland to dry. After it has been harvested, it must be stored for a short period, before it is transported. What amount of seaweed and for how long can it be stored without rotting?

Transport

Communication to mainland

Mapping tasks to robots

Energy

The PowerBuoy by OPT

With the climate crisis that humanity is facing, it would be highly unethical to use fossil fuels. Therefore, our farm will be powered on renewable energy sources. If system is capable of generating its own energy, it will be a lot more autonomous and low on maintenance. The most used renewable energy sources are wind and solar. However, the ocean offers many alternatives. Wave energy would be the most suitable for our design, because it does not require temperature differences, large surface areas, or specific locations. There are many different technologies for harnessing energy from the waves, ours must remain at one spot and be small. The powerbuoy developped by "Ocean power technologies" meets these requirements. The smallest version has a power capacity of 8400 Wh/Day at 80% availability.


Energy Requirements

  • The robot's motors use 27 kW/h but only move seperately, the robot can run for 3 hours after fully charging.
  • Communication:

Scalability

The farm will be square, ?*? meters for efficient charging anfd functioning of the robot. The seaweed will grow 2 meters beneath the surface to avoid over exposure to light. Vertical lines will be 5 meters long and 2 meters apart. To keep them straight, a weight of 400 grsams will be attached.

Benefits and drawbacks

Benefits

Drawbacks

The robots behaviour underwater would generate sound. Although the underwater world might seem silent to humans, fish experience sound intensly. The effects of human generated sounds on fish might therefore be harmful. Research results vary from little to no effect, to immediate death. Because the variety of sounds and fish is so large, we will try to minimize the sound level but not take extra measures to protect the fish from our robot's noices.

Big Data and IoT

The farm comes equipped with a lot of sensors to monitor its own condition and its enviroment. Using all of this data one can analyze it in real time, and after collecting more data extrapolate long-term trends. With all the robotic agents on the farm, combined with the data collected, the farm can be administrated remotely. The farm can be made smart to send out maintenance calls on its.

Science

The data collected by the farm and its robots can be shared with scientists and governments. More farms mean more sensors and thus a larger sensor size. This data would for example be very useful to The European Marine Observation and Data Network (EMODnet) on which engineers and scientist can find all the data available about the european waters. The European Commission has started Marine Knowledge 2020 with the aim to bring to bring all of the marine data from different sources together. This initiative examplifies the need for marine data.

Robot prototype

Design process

The design for the prototype consists of three components, one for the movement, one for grabbing and cutting and one for the Arduino and battery. The robot moves along a cable, for our prototype we will use a bicycle chain. The robot has three gearing wheels for a stable movement along the cable. The gearing wheel in the middle is driven by an engine. The component with the Arduino and the battery is hanging below the movement-component, just like a chairlift. This component should be heavy enough to sink, this is necessary to keep the bicycle chain on tension. This is the only component that should be waterproof, because it contains the Arduino and the battery. Below this component is the cut-and-grab-component, and is joined to the mothership with rope or a telescoping arm. This rope or telescoping arm is needed for a vertical movement, the robot should be able to cut at different depths. The claw should be able to grab seaweed that might have flowed away a bit, so the claw should be able to move horizontal. This happens by a telescoping arm. The scissors should be placed above the claw, otherwise the robot would cut seaweed that is not hold by the claw.

Technical description

Demonstration

Business and law

In 2014, the total annual value of produced seaweed was $6.4 billion. Worldwide, 93.8% of the global total production of aquatic plants came from aquaculture. Countries in East and Southeast Asia dominate seaweed culture production.[23] About 25 million tonnes of seaweeds and other algae are harvested annually for use as food, in cosmetics and fertilizers, and are processed to extract thickening agents or used as an additive to animal feed.[24] For the demand of food-grade seaweed to grow, there needs to be a dietary trend towards protein-rich vegetables, which seems to be the case. Growing the demand for seaweed requires a shift in the consumer's perception of seaweed as a food. Seaweed can be processed to be used as a source of nutrients for certain processed foods. There is increasing demand for seaweed as an agricultural supply, to use as animal food. It is also possible to use seaweed as a source for certain chemicals, i.e. for use in cosmetics.

Business case

Cost vs. profit

Laws

International law

European law

Dutch law

Looking ahead

Room for improvement

The robot in our design will operate from 2 to 7 meters below the surface. Our current prototype would not be fit to stand the such pressures (0.7845 bar for eight meters, to be sure.) In a commercial design, the robot have to be constructed more robust.

Future farms

The farm we have outlined only concerns the cultivation of seaweeds. However, farms can be augmented by employing bivalves in order to filter the water of pollutants.[25]

Recommendations

Horizon 2020

Applicable areas:

  • Agriculture & forestry
  • Aquatic resources
  • Bio-based industries
  • Environment & climate action
  • Food & healthy diet
  • Innovation
  • SME (small-medium enterprise)

Relevant research calls:

  • High value-added specialized vessel concepts enabling more efficient servicing of emerging coastal and offshore activities. (link) € 7 million
  • New sources of proteins for animal feed from co-products to address the EU protein gap. (link) € 15 million
  • Promoting and supporting the eco-intensification of aquaculture production systems: inland (including fresh water), coastal zone, and offshore. (link) € 6 million

Also Marine Knowledge 2020 with The European Marine Observation and Data Network (EMODnet), aims to collect a lot more data from the seas and oceans than we do at the moment.

Discussion

Conclusion

Sources and references

Sources


References

  1. Food security
  2. Food Security: The Challenge of Feeding 9 Billion People
  3. Agriculture & Forestry
  4. Agricultural Robotics and Automation
  5. Mariculture
  6. FAO Laminaria
  7. Seaweed Site
  8. Gelidium Amansii
  9. Nineteenth International Seaweed Symposium
  10. FAO Porphyra
  11. Growth, nitrogen and phosphorous uptake rates and O2 production rate of seaweeds cultured on coastal fish farms
  12. Serge Mabeau, Joël Fleurence: Seaweed in food products: biochemical and nutritional aspects (1993)
  13. P. Rupérez: Mineral content of edible marine seaweeds (2002)
  14. Joël Fleurence, Michele Morançais, Justine Dumay, Priscilla Decottignies, Vincent Turpin, Mathilde Munier, Nuria Garcia-Bueno and Pascal Jaouen: What are the prospects for using seaweed in human nutrition and for marine animals raised through aquaculture? (2012)
  15. Joël Fleurence: Seaweed proteins: biochemical, nutritional aspects and potential use (1999)
  16. 16.0 16.1 Holdt, Susan Løvstad, and Stefan Kraan. "Bioactive compounds in seaweed: functional food applications and legislation." Journal of Applied Phycology 23.3 (2011): 543-597.
  17. Arasaki, Seibun, and Teruko Arasaki. "Vegetables from the sea." Japan Publ. Inc., Tokyo 96 (1983): 251-223.
  18. Kumar, K. Suresh, K. Ganesan, and PV Subba Rao. "Antioxidant potential of solvent extracts of Kappaphycus alvarezii (Doty) Doty–An edible seaweed." Food chemistry 107.1 (2008): 289-295.
  19. Davide Anguita, Davide Brizzolara, Giancarlo Parodi. Building an Underwater Wireless Sensor Network based on Optical Communication: Research Challenges and Current Results.
  20. Ian F. Akyildiz, Dario Pompili, Tommaso Melodia. Underwater acoustic sensor networks: research challenges
  21. How do you determine if a sound affects a marine animal
  22. Ocean Energy Europe
  23. A guide to the seaweed industry
  24. The State of World Fisheries and Aquaculture 2014
  25. Biosorption and bioaccumulation of heavy metals by rock oyster Saccostrea cucullata in the Persian Gulf