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ERDOĞAN, HİLAL

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ERDOĞAN

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HİLAL

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Now showing 1 - 10 of 11
  • Publication
    Machine learning-based detection and severity assessment of sunflower powdery mildew: A precision agriculture approach
    (Bursa Uludağ Üniversitesi, 2023-09-18) Erdinç, Atilla; BÜTÜNER, ALPEREN KAAN; ŞAHİN, YAVUZ SELİM; ERDOĞAN, HİLAL
    Sunflower powdery mildew (Golovinomyces cichoracearum (DC.) V.P. Heluta) is a substantial threat to sunflower crops, causing significant yield loss. Traditional identification methods, based on human observation, fall short in providing early disease detection and quick control. This study presents a novel approach to this problem, utilizing machine learning for the early detection of powdery mildew in sunflowers. The disease severity levels were determined by training a Decision Trees model using matrix of soil, powdery mildew, stems, and leaf images obtained from original field images. It was detected disease severity levels of 18.14% and 5.56% in test images labeled as A and C, respectively. The model's demonstrated accuracy of 85% suggests high proficiency, indicating that machine learning, specifically the DTs model, holds promising prospects for revolutionizing disease control and diseases prevention in agriculture.
  • Publication
    Detection of cucurbit powdery mildew, sphaerotheca fuliginea (schlech.) thermal imaging in field conditions
    (Univ Agronomic Sciences & Veterinary Medicine Bucharest - Usamv, 2023-01-01) Erdoğan, Hilal; ERDOĞAN, HİLAL; Bütüner, Alperen Kaan; BÜTÜNER, ALPEREN KAAN; Şahin, Yavuz Selim; ŞAHİN, YAVUZ SELİM; Ziraat Fakültesi; Biyosistem Mühendisliği Bölümü; 0000-0002-0387-2600; AAP-5834-2020; AAH-2823-2021
    Plant diseases are one of the leading causes of yield losses in agricultural areas. In the fight against these diseases, chemical control methods are frequently used. However, this method of combat usually begins after the disease has spread throughout the entire field. The most essential thing here is to control the disease before it spreads throughout the entire country. Thermal imaging methods can now be used to accomplish this. Plant diseases stress the plant as a result of infection. The plant's stress causes activities that cause a temperature increase or reduction in the area where the infection has occurred or has begun. Thermal imaging technologies can be used to identify this condition. This work focuses on the potential early detection of Cucurbit powdery mildew (Sphaerotheca fuliginea (Schlech.) Polacci), which causes considerable yield loss in Cucurbitaceae, utilizing thermal imaging technologies. According to the findings, the lowest temperature in infected leaf tissues was 8.2 degrees C, whereas the maximum temperature in plant tissues without infection was 10.2 degrees C. The findings suggest that thermal imaging technology could be used to identify powdery mildew in cucurbits. In this case, early detection will potentially enable the detection of the disease that has started to spread in a certain region and will allow the disease to be potentially controlled with less labor and chemical use.
  • Publication
    Potential for early detection of powdery mildew in okra under field conditions using thermal imaging
    (Univ Agronomic Sciences & Veterinary Medicine Bucharest - Usamv, 2023-01-01) ŞAHİN, YAVUZ SELİM; BÜTÜNER, ALPEREN KAAN; Bütüner, Alperen Kaan; Erdoğan, Hilal; ERDOĞAN, HİLAL; Ziraat Fakültesi; Biyosistem Mühendisliği Bölümü; 0000-0002-0387-2600; AAP-5834-2020; AAH-2823-2021
    In recent years, apprehensions surrounding the pervasive employment of chemical control methods in global agricultural production have intensified, primarily due to their detrimental effects on non-target organisms. This situation accentuates the importance of technology-driven alternatives for managing plant diseases in agriculture. One such technological innovation, thermal imaging technology, has emerged as a promising tool for the early detection of plant diseases. Infections often induce stress in plants, leading to either elevated or reduced temperatures at the point of infection. It is postulated that thermal imaging may effectively identify such temperature deviations in plant tissues afflicted by disease during the initial stages. The study investigated temperature differences in leaves infected by Erysiphe cichoracearum, with disparities up to 1.6 degrees C. Over three weeks, the surface temperatures of numerous leaves were analysed at 30-minute intervals. In three weeks period, it was shown that infected leaf surfaces had significantly lower average daily temperatures than ambient and healthy leaf temperatures. Furthermore, healthy leaf temperatures remained consistently lower than ambient temperatures throughout the study.
  • Publication
    Precision application of the entomopathogenic nematode Heterorhabditis bacteriophora as a biological control agent through the Nemabot
    (Elsevier Sci Ltd, 2023-09-21) Erdoğan, Hilal; Ünal, Halil; Susurluk, Alper; Lewis, Edwin E.; ERDOĞAN, HİLAL; ÜNAL, HALİL; SUSURLUK, İSMAİL ALPER; Ziraat Fakültesi; Biyosistem Mühendisliği Bölümü; 0000-0002-0387-2600; AAG-7131-2021; AAP-5834-2020; IHS-3745-2023
    One of the most important development trends of robots in agriculture is to enable highly precise applications that minimize amounts of chemical components that are harmful to the environment. Precision agriculture is fundamental and inevitable worldwide because it provides more yield to an increasing population, while at the same time reducing inputs. The purpose of this study was to apply entomopathogenic nematodes, which are insect parasites used as biological control agents, through Nemabot. A robotic system that can move in the X-Y-Z coordinate plane has an agitating mechanism for suspension based on water and entomopathogenic nematodes and can perform precise dosing with a peristaltic pump designed and produced as a prototype. The experimental results of the robot application on the exact point, volume, amount, and uniformity of dosing show that the proposed method can effectively solve the problem of applying entomopathogenic nematodes, which are economically more expensive than pesticides. The main contribution of this paper is the proposal of a method to solve the problem of applying the agents precisely. This is the first experiment in which biological control products were applied using a robotic system. A patent application (PCT/TR2019/050768) was made, and the patentability claims were approved and officially registered (TR2018 14310B).
  • Publication
    Infected host responses across entomopathogenic nematode phylogeny
    (Soc Nematologists, 2021-01-01) Erdoğan, Hilal; Stevens, Glen; Stevens, Asa; Shapiro-Ilan, David; Kaplan, Fatma; Alborn, Hans; Lewis, Edwin; ERDOĞAN, HİLAL; Ziraat Fakültesi; Biyosistem Mühendisliği Bölümü; AAP-5834-2020
    We used a phylogenetic framework to examine the relationship between entomopathogenic nematode (EPN) vertical dispersal and infectivity when EPNs are exposed to a mixture of compounds found in late-stage EPN-infected insect cadavers. EPNs from five phylogenetically close and distant species (Heterorhabditis bacteriophora, H. georgiana, H. megidis, H. indica and Steinernema feltiae) were exposed to cadaver macerate produced by their own species' infection and by H. bacteriophora infected hosts. We found that only three of the five species (H. bacteriophora, H. indica and S. feltiae) responded to exposure to their own macerate by increasing rates of dispersal. When we exposed all five species to a H. bacteriophora infected host macerate, we found that only H. bacteriophora responded by increasing dispersal, and that the most distantly related species (S. feltiae) essentially halted dispersal. These findings suggest that (1) responses to cadaver macerate vary, and (2) there may be a relationship between inherent dispersal rates and sensitivity to macerate exposure, as the most rapidly dispersing species (H. megidis) showed no response to macerate exposure.
  • Publication
    Conspecific and heterospecific dispersal effect of exometobolomes on some entomopathogenic nematode species
    (Soc Nematologists, 2022-12-10) Ulu, Tufan Can; Erdoğan, H.; Cruzado, K. R.; Sadic, B.; Lewis, E. E.; ERDOĞAN, HİLAL; Ziraat Fakültesi; Biyosistem Mühendisliği Bölümü; 0000-0002-0387-2600; AAP-5834-2020
  • Publication
    Field application of encapsulated entomopathogenic nematodes using a precision planter
    (Academic Press Inc Elsevier Science, 2023-04-28) Ulu, Tufan Can; ERDOĞAN, HİLAL; Ziraat Fakültesi; Biyosistem Mühendisliği Bölümü; 0000-0003-3640-1474; 0000-0002-0387-2600; AAP-5834-2020
    The use of entomopathogenic nematodes (EPNs) as a biological control agent in agriculture has shown efficacy against various soil-dwelling pests. Despite its potential, high production costs and inconsistent field efficiency remain significant challenges. Although EPNs can be applied using irrigation systems and spraying equipment, optimized applications are required. This study aimed to evaluate the feasibility of applying EPNs in gelatin capsules and planting with a precision planter. It was hypothesized that this method would lead to more controlled and uniform EPN application. The effects of EPN encapsulation on dispersal and field persistence in the soil were also investigated. Larval mortality for capsule applications was between 53 and 67% under field conditions, with no statistical difference compared to the drip irrigation applications. Dispersal trials were carried out using custom steel olfactometers, and capsule application did not have any adverse effects on the dispersal of infective juveniles for 24, 48 and 72 h. Persistence trials revealed no significant differences between the capsule and control groups, with a maximum persistence of 50 days. The results suggest that the capsule technique could be a promising option for large-scale EPN applications, and further optimization may lead to improved results.
  • Publication
    Entomopathogenic nematode dispensing robot: Nemabot
    (Elsevier, 2021-02-14) Erdoğan, Hilal; Ünal, Halil; Lewis, Edwin E.; ERDOĞAN, HİLAL; ÜNAL, HALİL; Ziraat Fakültesi; Biyosistem Mühendisliği Bölümü; 0000-0002-0387-2600; AAP-5834-2020; IHS-3745-2023
    Entomopathogenic nematodes (EPN) are obligate endoparasites of many insect species and they are important biocontrol agents. Application strategies that improve precision and reduce labor would increase their potential in many cropping systems. We developed a unique robotic system to apply EPNs to a surface area precisely. The robotic system picks up EPNs from a suspension in a reservoir with a peristaltic pump and transfers them to an exact point with an exact amount. Four suspensions were prepared with four concentrations of EPNs; 0.1, 0.2, 0.4 and 0.8 g of commercial EPN product per 2 L of water. All suspensions were applied in three different amounts of water (25, 50 and 100 mL per application). In total, 12 different applications were conducted with the robot. Conical falcon centrifuge tubes were used to collect applied EPNs. Five samples (10 ?l) were taken from collected 25, 50 and 100 mL EPN suspensions and the average nematode number in the samples were scaled to the whole suspension. Results of the experiments showed that all robot applications, except 25 mL?0.1 g dose, were not significantly different from those of the control treatment, application with a pipette.. Thus, the robotic system has been found to make consistent applications.
  • Publication
    Group joining behaviours in the entomopathogenic nematode steinernema glaseri
    (Elsevier, 2023-03-28) Stevens, Glen; Erdoğan, Hilal; Pimentel, Eleanor; Dotson, Jenna; Stevens, Asa; Shapiro-Ilan, David; Kaplan, Fatma; Schliekelman, Paul; Lewis, Edwin; ERDOĞAN, HİLAL; Ziraat Fakültesi; Biyosistem Mühendisliği Bölümü; AAP-5834-2020
    Aggregations of foraging animals are key aspects of their ecology, driving spatial patterns, resource access, and successful resource exploitation. Entomopathogenic/insect parasitic nematodes demonstrate aggregated population structures. However, there are gaps in our understanding of how different behaviours affect aggregation. To understand joining behaviour as a mechanism of aggregation, we examined the group movement and joining behaviour of the EPN species, Steinernema glaseri, in conspecific (S. glaseri) and heterospecific (S. carpocapsae and S. feltiae) assemblages. We assessed group movement of S. glaseri using a glass olfactometer where nematodes were added to the central hub and allowed to disperse into six arms towards cues at the ends. We measured movement in the absence of external cues, when host cues were present but uniform, and in response to both con- and heterospecific entomopathogenic nematodes. S. glaseri dispersed in a highly aggregated fashion both in the presence and absence of host cues. When conspecific nematodes were present in the olfactometer ends, S. glaseri readily moved towards and joined conspecific groups, particularly if those conspecifics had experienced host contact 48 h previously. When heterospecific nematodes were present in the ends, S. glaseri only appeared to preferentially join groups of S. feltiae with prior host contact. S. glaseri exhibited no propensity to join groups of S. carpocapsae regardless of prior host contact. Findings demonstrate context-dependent joining behaviours that may underlie aggregation in EPNs. These behaviours may lead to more effective mass attack and regulate interspecific competition among these insect parasites.
  • Publication
    How entomopathogenic nematodes accomplish group behaviors
    (Soc Nematologists, 2022-12-10) Lewis, Ed; Cruzado-Gutierrez, Karin; Stephens, G. N.; Shapiro-Ilan, D. I.; Kaplan, Fatma; Alborn, H.; Erdogan, Hilal; ERDOĞAN, HİLAL; Ziraat Fakültesi; Biyosistem Mühendisliği Bölümü; 0000-0002-0387-2600; AAP-5834-2020