Development of Agricultural Soil FBG Sensors
Of the overall arable lands, 23% of the world’s cultivated area is currently under salinity risk. Thus, preventing soil salinity with smart agricultural applications is listed as one of the most highlighted and urgent headlines of global agriculture policies. Proposed project mainly addresses fast and precise determination of soil salinity that causes an important economic cost in agricultural sector and to help initiate of preventive measures. Majority of soil salinity sensors have been developed in this regard suffer from matrix interference and long detection and response times. Therefore, field applications of such sensors are troublesome. As an alternative to conventionally used conductivity methods, optical fiber technology offers several advantages as a sensor in various application areas due to the lack of electromagnetic interference and ease of miniaturization. As Fiber Bragg Grating (FBG) sensors use optical measurement methods, they are more successful in terms of matrix interference. FBG type sensors comprise polymeric probes that interacts with the analyte. However, current examples of these sensors usually contain commercial and structurally simpler polymeric materials. In this context, shortening the sensor’s response time by developing complex polymeric probes that responds to salinity in a fast and precise manner stands as a novel and rational approach in FBG sensor design. In this call, fast and high swelling/shrinking response superabsorbent polymers (SAPs) with long side chains and flexible crosslinked networks will be developed as SAP coated FBG sensors.

Autonomous Pest Control Systems
Abstract: In greenhouses, spraying (for pest control) and seedling cutting operations are generally performed manually. Seedlings (fruits, vegetables, flowers, etc.) are arranged in a specific layout. There is a main road line and seedling lines which vertically cut this main road line. There are pipe fitted systems in the seedling lines for heating according to the weather conditions. These systems are located between two seedling lines. The subject of the project about is the development of a tank vehicle located in the main line and a semi-autonomous system that can control the seedling cutting and spraying operations on two seedling pipelines attached to it. This structure will be modular and it will consist of 3 units. 1- Tank vehicle operating on main line (tank and two vehicles which are working on seedling pipeline carrying system). 2- Modular 2 vehicles working on seedling pipelines. These vehicles have fixed motion system and other structures are modular (spraying or seedling cutting). a. The spraying process will spray a seedling line with the modular structure attached to each vehicle. b. For seedling cutting, the modular structure that works on seedling pipelines will perform seedling cutting operations on each line. The Aim of Project: Generally, spraying (for pest control) and seedling cutting operations are made manually with human power in greenhouses. Although there are vehicles which imported for spraying for in the greenhouses, there is not any information about a fully automatic vehicle for seedling cutting in the literatures. During the interviews with supervisors of two different greenhouses, it was stated that the spraying operations were carried out on average once a week and a team of at least 5 people was needed. Seedling cutting operation is done once a year and an average of 25 people to work for this operation were reported. The aim of the project is to develop a modular structure that can be controlled by application which has via semi-autonomous features, which can make seedling cutting or spraying according to need. In this way, it is possible to perform the process carried out with 1 people- (t ) minutes instead of with 5 person- (t) minutes for the spraying operation. Keywords: spraying, pest control, seedling cutting, nozzle, blade, automation, car, carrier, tank, seedling, pulverization. Innovative Aspects: 1. With its modular structure, it can be used in both spraying and seedling processes. 2. The main tank vehicle for spraying and the system with two auxiliary vehicles on it. 3. In the seedling cutting process, a single cutting system will be connected to two vehicles. 4. A system in which the quantity is determined will be developed by real-time humidity and temperature measurement of the spraying line. 5. The seedling cutting unit has the potential to generate output subject to patent application according to the findings and preliminary research in the conceptual design stage.

Bee colon health monitoring and data analysis with artificial intelligence methods
The main goal of the project is to develop the detection of the position of the bee queen in the hive and to develop passive tools for collecting other data and integrate them into smart beehive concept. From data captured by sensors and beekeepers, we build a cloud-based, comprehensive data warehouse that explores complex relationships, using up-to-date artificial intelligence techniques that provide new information for practical beekeepers and researchers as well.

Environmental and Automated Plant Protection Device
We are looking for partners with agricultural expertise (preferably academic institutions) to cooperate with and to lead our project for the validation of our innovative device, Hi-Maye. We have developed a plant protection device that generates in-situ ozone, manages the required dose according to environmental sensors and mixes with the water to be irrigated in greenhouses. The same molecule that protects the earth from extrusive effects is now being used to protect the plant, therefore reduce chemical pesticide usage. There is a huge market for sustainable technologies to replace chemical pesticides, as they keep on causing huge problems for the eco-system. Our device is residue-free as ozone becomes oxygen in a short-while and economically viable while decreasing the operational costs: labor-force. The device prototype was manufactured and successful results are being observed. We are keen on finding partners abroad to enable international validation and set routes and plans for future sales planning. As you can see from our background information, we are electrical engineers with master's level knowledge in sensor design and software, but we lack the agricultural part in our team. To be exact, we are looking for 1) experts in disease and pest outbreak prediction models in the greenhouse/ arable land; 2) owners of greenhouses/farms for the scalable trial of the device; 3) experts in technology validation: people that can help us carry the agricultural tests in trustworthy and safe fashion. Please don't hesitate to show your interest and you can write to me anytime at t.asgarli@gmail.com Thank you. Look forward to meeting impactful people.

Farm to Table
Turkey is one of the leading producers of raisins in the world. Raisins Differences between organic and conventional production are listed extensively in the literature. Organic farming is known to use no chemical fertilizers, is less energy intensive and supports biodiversity while reducing the risk of chemical residues resulting from application of herbicides, insecticides, and fungicides. Another aspect of organic production is record keeping on paper based systems. Conventional farming methods have more fossil fuel input and chemical applications as well as increased water usage. This is followed by loss of topsoil and loss of carbon storage in addition to CO2 emitted during intensive production. Historically improper storage of conventional dried raisins is a cause of concern due to mycotoxins such as Ochratoxin. Since raisins are a major export product, product with chemical residue and mycotoxins is a human health concern. This project proposes 24 month duration to see the impact of training farmers and applying organic methods in fields. First, a training for farmers conducted scientists in organic raisin growing and proper drying and storage conditions will be conducted. Training will also include an environmental impact calculation module where farmers can see the amount of CO2 produced, water and energy consumption during production. This module will serve two purposes. It will inform the farmer and keep record so data will be available for to use now and in the future. Second purpose of the data is to help consumer make informed decisions. Data will be communicated to the consumer at the time of purchase so they can make informed decisions. Concurrently, a new trial will be of planting sister crops such as hyssop and clover to provide farmer with an additional income and deliver cover for topsoil. A list of preselected indicators will be monitored in both conventional and organic fields for climate change.

HALYs IDentification: Innovative ICT tools for targeted monitoring and sustainable management of the brown marmorated stink bug and other pests.
The brown marmorated stink bug (Halyomorpha halys, briefly “H. halys”) is an emerging pest of global importance for many agricultural crops. Field monitoring is crucial to obtain information on the actual presence and abundance of Halys pest in order to organize timely and proper management actions, also because chemical control is proved to be unsatisfactory. Leaded by improving sustainability, we propose to replace common human-based monitoring of halys' pest both on the fields and on the fruit chain production with an autonomous monitoring system based on data collected with new emerging technologies (Unmanned Vehicles, Vision/Audio sensors, spectroscopy, Edge Computing, LoRa Communications) enhanced by Algorithmic and Machine Learning methods. The innovations achieved by this project will be extended and adapted as much as possible to other insect pests, such as hazelnut pest or carroty fly. Open data will be made available via cloud repository to the scientific community.

Developing the Sustainable Supply Chain System
The agricultural sector has an important share in both job creation and foreign trade transactions and therefore very important for the country's economy. A properly planned supply chain is required to minimize losses in agricultural products. Mersin, is the 5th rank in Turkey in agricultural production value and produces 2.6 million tons of fruit and 2.3 millon vegetables per year. There are deficiencies in supply chain management in our city with high production potential. For this reason, Mersin Provincial Directorate of Agriculture and Forestry has developted a supply chain software. Mersin, which has a wide agriculture production range, has 13 districts. This software is still used in 6 districts and only for 2 products. In the project implementation, we plan to visit our overseas partners related to the supply chain syteam, to develop existing software, to train the staff on software and to organize the “Sustainable Supply Chain Workshop”.

Foodblock
It gets increasingly important to have trusted and secure information about lifecycle events of products. Blockchains could provide invariable information about the full production and transportation line for groceries including ingredients and their origins. The Problem with blockchains is that current experience shows that the conceptualization, implementation, and validation of blockchain-enabled projects comes with a significant overhead in consulting and engineering. FoodBlock’s objective is creating a new toolbox for producing or processing agricultural and food products that will lower the friction of implementation of the blockchain into the existing platforms and systems. With this novel approach for implementing blockchains, we hope to increase the number of companies using the advantages of blockchains.

I GROW MY FUTURE WITH SMART AGRICULTURE
We're Vocational and Technical Anatolian High School in Turkey. We are working on IT, software, cloud computing and IoT. Our food and beverage services area will grow micro green, micro vegetable and edible flowers in the greenhouse. Our Hungarian (Magyar) partner will export our products. The experts of our Austrian partner will share information with us in growing the products in the greenhouse. Briefly, we will realize our project in partnership with Turkish, Spain and Hungarian (Magyar) .

Digitalization of Citrus Value Chain (DIGIT4CITRUS)
In this project with using Data Integration, we will improve traceability of supply chain of citrus for the improvement of supply chain linkages to enhance efficiency and effectiveness of production and distribution; and improvement of on-farm production practices. During the project we will set-up and pilot external traceability system for citrus with using ICT. This system to be tested in Turkey and Greece and Spain and will integrate key applications and services that will address the challenges presented above. System will record and follow the citrus come from farmers and are processed and/or distributed as end products for consumers. Therefore, the basis of all traceability systems will be the ability to identify citrus that move along the supply chain. In practice, traceability systems will record keeping systems that show the path of citrus from suppliers through intermediate steps to consumers.

Holistic digital communication channel between food producers and consumers
The aim of this project is to stimulating regional growth and innovations in the areas of agriculture and business by developing a two-way digital communication channel between food producers and consumers. The porous of the digital channel is to provide insight into choices and decisions of consumers and producers. Focus is on information transfer and visualization, and includes competence in areas of design, and environmental assessment with focus on life cycle perspective. The information gathered about the various food products will cover the entire production chain. Such knowledge can help food producers identify 'hot spots' in their production and improve their process to meet consumer needs and principles. Thus, it could increase the attractiveness and growth of the agricultural, and help to develop knowledge and practices within the food industry. The knowledge gathered in this project will used for further research activities in collaboration with industry and education.

Development of an integrated Information and Communication Technology (ICT) platform that includes from hive to table residue and odor (aroma) tracking system in hives for more reliable honey production
The Food Safety is getting more interest day by day all over the world. On the other hand improvement of technology is giving more advantages to ensure the Food Safety. The honey is one of the most consuming and adultered products around the globe. The beehives must be healthy for the quality of bee products. A healthy hive is a hive that is away from chemical residues such as pesticides and antibiotics. In this project, the gas composition in the environment will be measured with electrochemical (electronic nose) devices and the health and aroma status in the hive will be monitored. Through the data collected a system will be trained with machine learning algorithms and an artificial intelligence module that gives early warning will be developed. This artificial intelligence machine learning module will be supported with geographical information systems and data around apiary, as well as data from electrochemical sensors.