�ݺ�ߣshows by User: kumaresankummu

�ݺ�ߣshows by User: kumaresankummu / http://www.slideshare.net/images/logo.gif �ݺ�ߣshows by User: kumaresankummu / Thu, 12 Dec 2024 15:46:50 GMT �ݺ�ߣShare feed for �ݺ�ߣshows by User: kumaresankummu Plant growth regulators - Growth, Flowering and Fruiting.pdf /slideshow/plant-growth-regulators-growth-flowering-and-fruiting-pdf/274018693 plantgrowthregulators-growthfloweringandfruiting-241212154650-1c2830c7
Plant growth regulators (PGRs) are natural or synthetic compounds that influence the physiological processes of plants, including growth, flowering, and fruiting. In horticultural crops, PGRs such as auxins, gibberellins, cytokinins, ethylene, and abscisic acid play vital roles. Auxins promote cell elongation, root initiation, and fruit development. Gibberellins stimulate stem elongation, flowering, and seed germination. Cytokinins encourage cell division and delay leaf senescence. Ethylene regulates fruit ripening, flowering, and abscission, while abscisic acid is crucial for stress responses and seed dormancy. These regulators are extensively used in horticulture to enhance crop yield, improve fruit quality, and synchronize flowering and harvesting.]]>
Plant growth regulators (PGRs) are natural or synthetic compounds that influence the physiological processes of plants, including growth, flowering, and fruiting. In horticultural crops, PGRs such as auxins, gibberellins, cytokinins, ethylene, and abscisic acid play vital roles. Auxins promote cell elongation, root initiation, and fruit development. Gibberellins stimulate stem elongation, flowering, and seed germination. Cytokinins encourage cell division and delay leaf senescence. Ethylene regulates fruit ripening, flowering, and abscission, while abscisic acid is crucial for stress responses and seed dormancy. These regulators are extensively used in horticulture to enhance crop yield, improve fruit quality, and synchronize flowering and harvesting.]]> Thu, 12 Dec 2024 15:46:50 GMT /slideshow/plant-growth-regulators-growth-flowering-and-fruiting-pdf/274018693 kumaresankummu@slideshare.net(kumaresankummu) Plant growth regulators - Growth, Flowering and Fruiting.pdf kumaresankummu Plant growth regulators (PGRs) are natural or synthetic compounds that influence the physiological processes of plants, including growth, flowering, and fruiting. In horticultural crops, PGRs such as auxins, gibberellins, cytokinins, ethylene, and abscisic acid play vital roles. Auxins promote cell elongation, root initiation, and fruit development. Gibberellins stimulate stem elongation, flowering, and seed germination. Cytokinins encourage cell division and delay leaf senescence. Ethylene regulates fruit ripening, flowering, and abscission, while abscisic acid is crucial for stress responses and seed dormancy. These regulators are extensively used in horticulture to enhance crop yield, improve fruit quality, and synchronize flowering and harvesting. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/plantgrowthregulators-growthfloweringandfruiting-241212154650-1c2830c7-thumbnail.jpg?width=120&height=120&fit=bounds" /> Plant growth regulators (PGRs) are natural or synthetic compounds that influence the physiological processes of plants, including growth, flowering, and fruiting. In horticultural crops, PGRs such as auxins, gibberellins, cytokinins, ethylene, and abscisic acid play vital roles. Auxins promote cell elongation, root initiation, and fruit development. Gibberellins stimulate stem elongation, flowering, and seed germination. Cytokinins encourage cell division and delay leaf senescence. Ethylene regulates fruit ripening, flowering, and abscission, while abscisic acid is crucial for stress responses and seed dormancy. These regulators are extensively used in horticulture to enhance crop yield, improve fruit quality, and synchronize flowering and harvesting.

Plant growth regulators - Growth, Flowering and Fruiting.pdf from Dr. M. Kumaresan

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0 Pollination, Fruit set, Fruit drops, Causes of fruit drops, parthenocarpy and Parthenogenesis.pdf /slideshow/pollination-fruit-set-fruit-drops-causes-of-fruit-drops-parthenocarpy-and-parthenogenesis-pdf/274017837 pollinationfruitsetfruitdropscausesoffruitdropsparthenocarpyandparthenogenesis-241212145303-ee19b250
Pollination is the transfer of pollen from the anther to the stigma of a flower, enabling fertilization. It is a critical process for fruit set, which is the transformation of flowers into fruits following successful pollination and fertilization. Fruit drops refer to the shedding of fruits before maturity, which can occur due to physiological, environmental, or biotic factors. Common causes include hormonal imbalances, water stress, nutrient deficiencies, pest infestations, or poor pollination. Parthenocarpy is the development of fruits without fertilization, leading to seedless fruits, as seen in bananas and seedless grapes. It is a desirable trait in horticultural crops for market preference. Parthenogenesis involves the development of an embryo from an unfertilized egg, primarily observed in some plants. It contributes to seed production in certain crops and aids in breeding programs.]]>
Pollination is the transfer of pollen from the anther to the stigma of a flower, enabling fertilization. It is a critical process for fruit set, which is the transformation of flowers into fruits following successful pollination and fertilization. Fruit drops refer to the shedding of fruits before maturity, which can occur due to physiological, environmental, or biotic factors. Common causes include hormonal imbalances, water stress, nutrient deficiencies, pest infestations, or poor pollination. Parthenocarpy is the development of fruits without fertilization, leading to seedless fruits, as seen in bananas and seedless grapes. It is a desirable trait in horticultural crops for market preference. Parthenogenesis involves the development of an embryo from an unfertilized egg, primarily observed in some plants. It contributes to seed production in certain crops and aids in breeding programs.]]> Thu, 12 Dec 2024 14:53:03 GMT /slideshow/pollination-fruit-set-fruit-drops-causes-of-fruit-drops-parthenocarpy-and-parthenogenesis-pdf/274017837 kumaresankummu@slideshare.net(kumaresankummu) Pollination, Fruit set, Fruit drops, Causes of fruit drops, parthenocarpy and Parthenogenesis.pdf kumaresankummu Pollination is the transfer of pollen from the anther to the stigma of a flower, enabling fertilization. It is a critical process for fruit set, which is the transformation of flowers into fruits following successful pollination and fertilization. Fruit drops refer to the shedding of fruits before maturity, which can occur due to physiological, environmental, or biotic factors. Common causes include hormonal imbalances, water stress, nutrient deficiencies, pest infestations, or poor pollination. Parthenocarpy is the development of fruits without fertilization, leading to seedless fruits, as seen in bananas and seedless grapes. It is a desirable trait in horticultural crops for market preference. Parthenogenesis involves the development of an embryo from an unfertilized egg, primarily observed in some plants. It contributes to seed production in certain crops and aids in breeding programs. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/pollinationfruitsetfruitdropscausesoffruitdropsparthenocarpyandparthenogenesis-241212145303-ee19b250-thumbnail.jpg?width=120&height=120&fit=bounds" /> Pollination is the transfer of pollen from the anther to the stigma of a flower, enabling fertilization. It is a critical process for fruit set, which is the transformation of flowers into fruits following successful pollination and fertilization. Fruit drops refer to the shedding of fruits before maturity, which can occur due to physiological, environmental, or biotic factors. Common causes include hormonal imbalances, water stress, nutrient deficiencies, pest infestations, or poor pollination. Parthenocarpy is the development of fruits without fertilization, leading to seedless fruits, as seen in bananas and seedless grapes. It is a desirable trait in horticultural crops for market preference. Parthenogenesis involves the development of an embryo from an unfertilized egg, primarily observed in some plants. It contributes to seed production in certain crops and aids in breeding programs.

Pollination, Fruit set, Fruit drops, Causes of fruit drops, parthenocarpy and Parthenogenesis.pdf from Dr. M. Kumaresan

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0 Micro- Propagation - Culturing Plant Tissues and Organs /slideshow/micro-propagation-culturing-plant-tissues-and-organs/274017534 micro-propagation-241212143936-c290a1ac
Micropropagation is a modern technique of plant tissue culture used to rapidly multiply and produce disease-free planting materials. It involves growing plants in a controlled, sterile environment using small plant tissues, such as meristems, under laboratory conditions. This method is widely used in horticultural crops like fruits, vegetables, ornamentals, and medicinal plants to ensure uniformity, high yield, and quick propagation. It offers advantages such as producing a large number of plants in a short time, preserving elite genotypes, and enabling year-round cultivation independent of seasons.]]>
Micropropagation is a modern technique of plant tissue culture used to rapidly multiply and produce disease-free planting materials. It involves growing plants in a controlled, sterile environment using small plant tissues, such as meristems, under laboratory conditions. This method is widely used in horticultural crops like fruits, vegetables, ornamentals, and medicinal plants to ensure uniformity, high yield, and quick propagation. It offers advantages such as producing a large number of plants in a short time, preserving elite genotypes, and enabling year-round cultivation independent of seasons.]]> Thu, 12 Dec 2024 14:39:36 GMT /slideshow/micro-propagation-culturing-plant-tissues-and-organs/274017534 kumaresankummu@slideshare.net(kumaresankummu) Micro- Propagation - Culturing Plant Tissues and Organs kumaresankummu Micropropagation is a modern technique of plant tissue culture used to rapidly multiply and produce disease-free planting materials. It involves growing plants in a controlled, sterile environment using small plant tissues, such as meristems, under laboratory conditions. This method is widely used in horticultural crops like fruits, vegetables, ornamentals, and medicinal plants to ensure uniformity, high yield, and quick propagation. It offers advantages such as producing a large number of plants in a short time, preserving elite genotypes, and enabling year-round cultivation independent of seasons. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/micro-propagation-241212143936-c290a1ac-thumbnail.jpg?width=120&height=120&fit=bounds" /> Micropropagation is a modern technique of plant tissue culture used to rapidly multiply and produce disease-free planting materials. It involves growing plants in a controlled, sterile environment using small plant tissues, such as meristems, under laboratory conditions. This method is widely used in horticultural crops like fruits, vegetables, ornamentals, and medicinal plants to ensure uniformity, high yield, and quick propagation. It offers advantages such as producing a large number of plants in a short time, preserving elite genotypes, and enabling year-round cultivation independent of seasons.

Micro- Propagation - Culturing Plant Tissues and Organs from Dr. M. Kumaresan

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0 Crop Regulatory Practices in Horticultural Crops.pdf /slideshow/crop-regulatory-practices-in-horticultural-crops-pdf/274017419 cropregulatorypractices-241212143212-5bae648a
Crop regulatory practices in horticultural crops involve techniques to optimize plant growth, enhance yield, and improve quality. These practices include pruning, thinning, and training to manage canopy structure, ensuring better light penetration and air circulation. Growth regulators, such as auxins, gibberellins, and ethylene, are often used to control flowering, fruit setting, and ripening. Proper irrigation scheduling, nutrient management, and pest control are also critical for maintaining plant health and productivity. These practices help achieve uniform growth, improve marketability, and reduce losses in crops like fruits, vegetables, and ornamental plants.]]>
Crop regulatory practices in horticultural crops involve techniques to optimize plant growth, enhance yield, and improve quality. These practices include pruning, thinning, and training to manage canopy structure, ensuring better light penetration and air circulation. Growth regulators, such as auxins, gibberellins, and ethylene, are often used to control flowering, fruit setting, and ripening. Proper irrigation scheduling, nutrient management, and pest control are also critical for maintaining plant health and productivity. These practices help achieve uniform growth, improve marketability, and reduce losses in crops like fruits, vegetables, and ornamental plants.]]> Thu, 12 Dec 2024 14:32:11 GMT /slideshow/crop-regulatory-practices-in-horticultural-crops-pdf/274017419 kumaresankummu@slideshare.net(kumaresankummu) Crop Regulatory Practices in Horticultural Crops.pdf kumaresankummu Crop regulatory practices in horticultural crops involve techniques to optimize plant growth, enhance yield, and improve quality. These practices include pruning, thinning, and training to manage canopy structure, ensuring better light penetration and air circulation. Growth regulators, such as auxins, gibberellins, and ethylene, are often used to control flowering, fruit setting, and ripening. Proper irrigation scheduling, nutrient management, and pest control are also critical for maintaining plant health and productivity. These practices help achieve uniform growth, improve marketability, and reduce losses in crops like fruits, vegetables, and ornamental plants. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/cropregulatorypractices-241212143212-5bae648a-thumbnail.jpg?width=120&height=120&fit=bounds" /> Crop regulatory practices in horticultural crops involve techniques to optimize plant growth, enhance yield, and improve quality. These practices include pruning, thinning, and training to manage canopy structure, ensuring better light penetration and air circulation. Growth regulators, such as auxins, gibberellins, and ethylene, are often used to control flowering, fruit setting, and ripening. Proper irrigation scheduling, nutrient management, and pest control are also critical for maintaining plant health and productivity. These practices help achieve uniform growth, improve marketability, and reduce losses in crops like fruits, vegetables, and ornamental plants.

Crop Regulatory Practices in Horticultural Crops.pdf from Dr. M. Kumaresan

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0 Spatial data and their management in GIS.pdf /slideshow/spatial-data-and-their-management-in-gis-pdf/274003099 spatialdataandtheirmanagementingis-241212012925-d2927fe2
Spatial data management in a Geographic Information System (GIS) involves storing and organizing spatial data in a computer. Spatial data is information that has a locational attribute, such as the size, shape, or location of an object. GIS uses specialized software to access, visualize, and analyze spatial data. Aspects of spatial data management in GIS: Data capture: Storing spatial data in a computer Database creation: Organizing spatial data in a computer Data types: Spatial data can be represented as points, lines, polygons, or pixels. It can also include images as rasters, which are grids of pixels. Data storage: Spatial data is often stored as coordinates and topology. Data analysis: GIS tools can be used to analyze spatial data. Data collection: Spatial data can be collected from a variety of sources, including ground surveys, census studies, land records, satellite images, aerial photographs, and GPS receivers. Data joins: Joins can be used to combine feature information based on spatial location and association. Relates: Relates can be used to temporarily associate two map layers or tables. ]]>
Spatial data management in a Geographic Information System (GIS) involves storing and organizing spatial data in a computer. Spatial data is information that has a locational attribute, such as the size, shape, or location of an object. GIS uses specialized software to access, visualize, and analyze spatial data. Aspects of spatial data management in GIS: Data capture: Storing spatial data in a computer Database creation: Organizing spatial data in a computer Data types: Spatial data can be represented as points, lines, polygons, or pixels. It can also include images as rasters, which are grids of pixels. Data storage: Spatial data is often stored as coordinates and topology. Data analysis: GIS tools can be used to analyze spatial data. Data collection: Spatial data can be collected from a variety of sources, including ground surveys, census studies, land records, satellite images, aerial photographs, and GPS receivers. Data joins: Joins can be used to combine feature information based on spatial location and association. Relates: Relates can be used to temporarily associate two map layers or tables. ]]> Thu, 12 Dec 2024 01:29:25 GMT /slideshow/spatial-data-and-their-management-in-gis-pdf/274003099 kumaresankummu@slideshare.net(kumaresankummu) Spatial data and their management in GIS.pdf kumaresankummu Spatial data management in a Geographic Information System (GIS) involves storing and organizing spatial data in a computer. Spatial data is information that has a locational attribute, such as the size, shape, or location of an object. GIS uses specialized software to access, visualize, and analyze spatial data. Aspects of spatial data management in GIS: Data capture: Storing spatial data in a computer Database creation: Organizing spatial data in a computer Data types: Spatial data can be represented as points, lines, polygons, or pixels. It can also include images as rasters, which are grids of pixels. Data storage: Spatial data is often stored as coordinates and topology. Data analysis: GIS tools can be used to analyze spatial data. Data collection: Spatial data can be collected from a variety of sources, including ground surveys, census studies, land records, satellite images, aerial photographs, and GPS receivers. Data joins: Joins can be used to combine feature information based on spatial location and association. Relates: Relates can be used to temporarily associate two map layers or tables. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/spatialdataandtheirmanagementingis-241212012925-d2927fe2-thumbnail.jpg?width=120&height=120&fit=bounds" /> Spatial data management in a Geographic Information System (GIS) involves storing and organizing spatial data in a computer. Spatial data is information that has a locational attribute, such as the size, shape, or location of an object. GIS uses specialized software to access, visualize, and analyze spatial data. Aspects of spatial data management in GIS: Data capture: Storing spatial data in a computer Database creation: Organizing spatial data in a computer Data types: Spatial data can be represented as points, lines, polygons, or pixels. It can also include images as rasters, which are grids of pixels. Data storage: Spatial data is often stored as coordinates and topology. Data analysis: GIS tools can be used to analyze spatial data. Data collection: Spatial data can be collected from a variety of sources, including ground surveys, census studies, land records, satellite images, aerial photographs, and GPS receivers. Data joins: Joins can be used to combine feature information based on spatial location and association. Relates: Relates can be used to temporarily associate two map layers or tables.

Spatial data and their management in GIS.pdf from Dr. M. Kumaresan

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0 Geo-informatics- definition, concepts, tools and techniques; their use in Precision Agriculture /slideshow/geo-informatics-definition-concepts-tools-and-techniques-their-use-in-precision-agriculture/274002901 geo-informatics-definitionconceptstools-241212011728-60db8ee3
Geoinformatics is the science and technology of capturing, storing, and analyzing spatial information to solve problems in Earth sciences. It's used in precision agriculture to improve crop yields and reduce environmental impact. Some of the tools and techniques used in geoinformatics include: Remote sensing Uses sensors mounted on platforms like satellites, aircraft, or balloons to collect radiation and make inferences about objects without physical contact. Remote sensing can be used to model crop yields, identify pests, and monitor irrigation. Global positioning system (GPS) Provides real-time 3D positioning and navigation. GPS can be used for farm planning, tractor guidance, and yield mapping. Geographic information system (GIS) A computerized system for storing and analyzing spatial data. GIS can be used to create maps that show how yield, fertility, pests, and other factors interact. Soil mapping Uses remote sensing and GIS to collect and analyze data about soil characteristics. Soil maps can help farmers identify variations in soil properties and apply fertilizers and irrigation more accurately]]>
Geoinformatics is the science and technology of capturing, storing, and analyzing spatial information to solve problems in Earth sciences. It's used in precision agriculture to improve crop yields and reduce environmental impact. Some of the tools and techniques used in geoinformatics include: Remote sensing Uses sensors mounted on platforms like satellites, aircraft, or balloons to collect radiation and make inferences about objects without physical contact. Remote sensing can be used to model crop yields, identify pests, and monitor irrigation. Global positioning system (GPS) Provides real-time 3D positioning and navigation. GPS can be used for farm planning, tractor guidance, and yield mapping. Geographic information system (GIS) A computerized system for storing and analyzing spatial data. GIS can be used to create maps that show how yield, fertility, pests, and other factors interact. Soil mapping Uses remote sensing and GIS to collect and analyze data about soil characteristics. Soil maps can help farmers identify variations in soil properties and apply fertilizers and irrigation more accurately]]> Thu, 12 Dec 2024 01:17:28 GMT /slideshow/geo-informatics-definition-concepts-tools-and-techniques-their-use-in-precision-agriculture/274002901 kumaresankummu@slideshare.net(kumaresankummu) Geo-informatics- definition, concepts, tools and techniques; their use in Precision Agriculture kumaresankummu Geoinformatics is the science and technology of capturing, storing, and analyzing spatial information to solve problems in Earth sciences. It's used in precision agriculture to improve crop yields and reduce environmental impact. Some of the tools and techniques used in geoinformatics include: Remote sensing Uses sensors mounted on platforms like satellites, aircraft, or balloons to collect radiation and make inferences about objects without physical contact. Remote sensing can be used to model crop yields, identify pests, and monitor irrigation. Global positioning system (GPS) Provides real-time 3D positioning and navigation. GPS can be used for farm planning, tractor guidance, and yield mapping. Geographic information system (GIS) A computerized system for storing and analyzing spatial data. GIS can be used to create maps that show how yield, fertility, pests, and other factors interact. Soil mapping Uses remote sensing and GIS to collect and analyze data about soil characteristics. Soil maps can help farmers identify variations in soil properties and apply fertilizers and irrigation more accurately <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/geo-informatics-definitionconceptstools-241212011728-60db8ee3-thumbnail.jpg?width=120&height=120&fit=bounds" /> Geoinformatics is the science and technology of capturing, storing, and analyzing spatial information to solve problems in Earth sciences. It's used in precision agriculture to improve crop yields and reduce environmental impact. Some of the tools and techniques used in geoinformatics include: Remote sensing Uses sensors mounted on platforms like satellites, aircraft, or balloons to collect radiation and make inferences about objects without physical contact. Remote sensing can be used to model crop yields, identify pests, and monitor irrigation. Global positioning system (GPS) Provides real-time 3D positioning and navigation. GPS can be used for farm planning, tractor guidance, and yield mapping. Geographic information system (GIS) A computerized system for storing and analyzing spatial data. GIS can be used to create maps that show how yield, fertility, pests, and other factors interact. Soil mapping Uses remote sensing and GIS to collect and analyze data about soil characteristics. Soil maps can help farmers identify variations in soil properties and apply fertilizers and irrigation more accurately

Geo-informatics- definition, concepts, tools and techniques; their use in Precision Agriculture from Dr. M. Kumaresan

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0 Geographic Information System (GIS) and Its Application in Precision Farming /slideshow/geographic-information-system-gis-and-its-application-in-precision-farming-89df/274002757 geographicinformationsystemgis-241212010708-41df997c
A geographic information system (GIS) is a computer-based tool that stores, analyzes, and displays information about locations on Earth: GIS combines database operations like statistical analysis and queries with the visualization and geographic analysis capabilities of maps. It can be used to: Analyze patterns and relationships, Make informed decisions, Solve social and business challenges, Improve logistics, Plan for extreme weather events]]>
A geographic information system (GIS) is a computer-based tool that stores, analyzes, and displays information about locations on Earth: GIS combines database operations like statistical analysis and queries with the visualization and geographic analysis capabilities of maps. It can be used to: Analyze patterns and relationships, Make informed decisions, Solve social and business challenges, Improve logistics, Plan for extreme weather events]]> Thu, 12 Dec 2024 01:07:08 GMT /slideshow/geographic-information-system-gis-and-its-application-in-precision-farming-89df/274002757 kumaresankummu@slideshare.net(kumaresankummu) Geographic Information System (GIS) and Its Application in Precision Farming kumaresankummu A geographic information system (GIS) is a computer-based tool that stores, analyzes, and displays information about locations on Earth: GIS combines database operations like statistical analysis and queries with the visualization and geographic analysis capabilities of maps. It can be used to: Analyze patterns and relationships, Make informed decisions, Solve social and business challenges, Improve logistics, Plan for extreme weather events <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/geographicinformationsystemgis-241212010708-41df997c-thumbnail.jpg?width=120&height=120&fit=bounds" /> A geographic information system (GIS) is a computer-based tool that stores, analyzes, and displays information about locations on Earth: GIS combines database operations like statistical analysis and queries with the visualization and geographic analysis capabilities of maps. It can be used to: Analyze patterns and relationships, Make informed decisions, Solve social and business challenges, Improve logistics, Plan for extreme weather events

Geographic Information System (GIS) and Its Application in Precision Farming from Dr. M. Kumaresan

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0 Soil mapping; Fertilizer recommendation using geospatial technologies.pdf /slideshow/soil-mapping-fertilizer-recommendation-using-geospatial-technologies-pdf/273978227 soilmappingfertilizerrecommendationusinggeospatialtechnologies-241211012011-b1f95030
Soil mapping using geospatial technologies involves the use of satellite imagery, remote sensing, and soil sensors to create detailed maps of soil properties like pH, texture, nutrient levels, and organic matter. This data helps identify variations across a field, allowing for more informed and targeted fertilizer recommendations. By combining GIS (Geographic Information Systems) and Variable Rate Technology (VRT), fertilizers can be applied precisely according to the specific needs of different soil zones. This ensures efficient use of resources, reduces environmental impact, and enhances crop yields by optimizing nutrient management.]]>
Soil mapping using geospatial technologies involves the use of satellite imagery, remote sensing, and soil sensors to create detailed maps of soil properties like pH, texture, nutrient levels, and organic matter. This data helps identify variations across a field, allowing for more informed and targeted fertilizer recommendations. By combining GIS (Geographic Information Systems) and Variable Rate Technology (VRT), fertilizers can be applied precisely according to the specific needs of different soil zones. This ensures efficient use of resources, reduces environmental impact, and enhances crop yields by optimizing nutrient management.]]> Wed, 11 Dec 2024 01:20:11 GMT /slideshow/soil-mapping-fertilizer-recommendation-using-geospatial-technologies-pdf/273978227 kumaresankummu@slideshare.net(kumaresankummu) Soil mapping; Fertilizer recommendation using geospatial technologies.pdf kumaresankummu Soil mapping using geospatial technologies involves the use of satellite imagery, remote sensing, and soil sensors to create detailed maps of soil properties like pH, texture, nutrient levels, and organic matter. This data helps identify variations across a field, allowing for more informed and targeted fertilizer recommendations. By combining GIS (Geographic Information Systems) and Variable Rate Technology (VRT), fertilizers can be applied precisely according to the specific needs of different soil zones. This ensures efficient use of resources, reduces environmental impact, and enhances crop yields by optimizing nutrient management. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/soilmappingfertilizerrecommendationusinggeospatialtechnologies-241211012011-b1f95030-thumbnail.jpg?width=120&height=120&fit=bounds" /> Soil mapping using geospatial technologies involves the use of satellite imagery, remote sensing, and soil sensors to create detailed maps of soil properties like pH, texture, nutrient levels, and organic matter. This data helps identify variations across a field, allowing for more informed and targeted fertilizer recommendations. By combining GIS (Geographic Information Systems) and Variable Rate Technology (VRT), fertilizers can be applied precisely according to the specific needs of different soil zones. This ensures efficient use of resources, reduces environmental impact, and enhances crop yields by optimizing nutrient management.

Soil mapping; Fertilizer recommendation using geospatial technologies.pdf from Dr. M. Kumaresan

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0 Crop Discrimination and Yield Monitoring in Precision Agriculture.pdf /slideshow/crop-discrimination-and-yield-monitoring-in-precision-agriculture-pdf/273978072 cropdiscriminationandyieldmonitoringinprecisionagriculture-241211010709-b7773bcf
Crop discrimination and yield monitoring are key components of precision agriculture, aimed at optimizing crop management and maximizing productivity. Crop discrimination involves using remote sensing technologies, such as satellite imagery and drones, to differentiate between various crop types within a field based on their unique spectral signatures. This helps in creating precise field maps and managing crops individually based on their needs. Yield monitoring uses technologies like GPS-enabled harvesters, soil sensors, and remote sensing to track crop growth and predict yields accurately. By collecting real-time data, farmers can make informed decisions regarding irrigation, fertilization, and pest management, leading to increased efficiency, reduced costs, and sustainable farming practices.]]>
Crop discrimination and yield monitoring are key components of precision agriculture, aimed at optimizing crop management and maximizing productivity. Crop discrimination involves using remote sensing technologies, such as satellite imagery and drones, to differentiate between various crop types within a field based on their unique spectral signatures. This helps in creating precise field maps and managing crops individually based on their needs. Yield monitoring uses technologies like GPS-enabled harvesters, soil sensors, and remote sensing to track crop growth and predict yields accurately. By collecting real-time data, farmers can make informed decisions regarding irrigation, fertilization, and pest management, leading to increased efficiency, reduced costs, and sustainable farming practices.]]> Wed, 11 Dec 2024 01:07:09 GMT /slideshow/crop-discrimination-and-yield-monitoring-in-precision-agriculture-pdf/273978072 kumaresankummu@slideshare.net(kumaresankummu) Crop Discrimination and Yield Monitoring in Precision Agriculture.pdf kumaresankummu Crop discrimination and yield monitoring are key components of precision agriculture, aimed at optimizing crop management and maximizing productivity. Crop discrimination involves using remote sensing technologies, such as satellite imagery and drones, to differentiate between various crop types within a field based on their unique spectral signatures. This helps in creating precise field maps and managing crops individually based on their needs. Yield monitoring uses technologies like GPS-enabled harvesters, soil sensors, and remote sensing to track crop growth and predict yields accurately. By collecting real-time data, farmers can make informed decisions regarding irrigation, fertilization, and pest management, leading to increased efficiency, reduced costs, and sustainable farming practices. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/cropdiscriminationandyieldmonitoringinprecisionagriculture-241211010709-b7773bcf-thumbnail.jpg?width=120&height=120&fit=bounds" /> Crop discrimination and yield monitoring are key components of precision agriculture, aimed at optimizing crop management and maximizing productivity. Crop discrimination involves using remote sensing technologies, such as satellite imagery and drones, to differentiate between various crop types within a field based on their unique spectral signatures. This helps in creating precise field maps and managing crops individually based on their needs. Yield monitoring uses technologies like GPS-enabled harvesters, soil sensors, and remote sensing to track crop growth and predict yields accurately. By collecting real-time data, farmers can make informed decisions regarding irrigation, fertilization, and pest management, leading to increased efficiency, reduced costs, and sustainable farming practices.

Crop Discrimination and Yield Monitoring in Precision Agriculture.pdf from Dr. M. Kumaresan

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0 Definition, Concepts, Techniques and Issues of Precision Agriculture.pdf /slideshow/definition-concepts-techniques-and-issues-of-precision-agriculture-pdf/273977779 definitionconceptstechniquesandissuesofprecisionagriculture-241211004518-f486669e
Precision Agriculture is an innovative farming approach that uses technology to optimize field-level management regarding crop production and resource use. It involves the use of satellite imagery, GPS, drones, and soil sensors to monitor and manage agricultural operations more efficiently. Key concepts include site-specific management, where inputs like water, fertilizers, and pesticides are applied precisely based on field variability. Common techniques used in precision agriculture include Variable Rate Technology (VRT), remote sensing, and yield monitoring. Despite its potential, there are several challenges, including high implementation costs, lack of infrastructure, and limited farmer knowledge about these technologies. Additionally, issues like small landholdings and climate variability hinder widespread adoption in countries like India.]]>
Precision Agriculture is an innovative farming approach that uses technology to optimize field-level management regarding crop production and resource use. It involves the use of satellite imagery, GPS, drones, and soil sensors to monitor and manage agricultural operations more efficiently. Key concepts include site-specific management, where inputs like water, fertilizers, and pesticides are applied precisely based on field variability. Common techniques used in precision agriculture include Variable Rate Technology (VRT), remote sensing, and yield monitoring. Despite its potential, there are several challenges, including high implementation costs, lack of infrastructure, and limited farmer knowledge about these technologies. Additionally, issues like small landholdings and climate variability hinder widespread adoption in countries like India.]]> Wed, 11 Dec 2024 00:45:18 GMT /slideshow/definition-concepts-techniques-and-issues-of-precision-agriculture-pdf/273977779 kumaresankummu@slideshare.net(kumaresankummu) Definition, Concepts, Techniques and Issues of Precision Agriculture.pdf kumaresankummu Precision Agriculture is an innovative farming approach that uses technology to optimize field-level management regarding crop production and resource use. It involves the use of satellite imagery, GPS, drones, and soil sensors to monitor and manage agricultural operations more efficiently. Key concepts include site-specific management, where inputs like water, fertilizers, and pesticides are applied precisely based on field variability. Common techniques used in precision agriculture include Variable Rate Technology (VRT), remote sensing, and yield monitoring. Despite its potential, there are several challenges, including high implementation costs, lack of infrastructure, and limited farmer knowledge about these technologies. Additionally, issues like small landholdings and climate variability hinder widespread adoption in countries like India. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/definitionconceptstechniquesandissuesofprecisionagriculture-241211004518-f486669e-thumbnail.jpg?width=120&height=120&fit=bounds" /> Precision Agriculture is an innovative farming approach that uses technology to optimize field-level management regarding crop production and resource use. It involves the use of satellite imagery, GPS, drones, and soil sensors to monitor and manage agricultural operations more efficiently. Key concepts include site-specific management, where inputs like water, fertilizers, and pesticides are applied precisely based on field variability. Common techniques used in precision agriculture include Variable Rate Technology (VRT), remote sensing, and yield monitoring. Despite its potential, there are several challenges, including high implementation costs, lack of infrastructure, and limited farmer knowledge about these technologies. Additionally, issues like small landholdings and climate variability hinder widespread adoption in countries like India.

Definition, Concepts, Techniques and Issues of Precision Agriculture.pdf from Dr. M. Kumaresan

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0 Global positioning system (GPS), components and its functions.pdf /slideshow/global-positioning-system-gps-components-and-its-functions-pdf/273977463 globalpositioningsystemgpscomponentsanditsfunctions-241211002311-ade671d9
The Global Positioning System (GPS) is a satellite-based navigation system that provides accurate location, navigation, and timing information worldwide. It consists of three main components: the space segment (satellites orbiting the Earth), the control segment (ground stations that monitor and maintain the satellites), and the user segment (GPS receivers used by individuals and devices). The satellites transmit signals, which are received by GPS receivers to calculate precise positioning. The control segment ensures the accuracy of satellite data, while the user segment interprets this data to determine location. Together, these components enable GPS to support a wide range of applications, from navigation to mapping and timing.]]>
The Global Positioning System (GPS) is a satellite-based navigation system that provides accurate location, navigation, and timing information worldwide. It consists of three main components: the space segment (satellites orbiting the Earth), the control segment (ground stations that monitor and maintain the satellites), and the user segment (GPS receivers used by individuals and devices). The satellites transmit signals, which are received by GPS receivers to calculate precise positioning. The control segment ensures the accuracy of satellite data, while the user segment interprets this data to determine location. Together, these components enable GPS to support a wide range of applications, from navigation to mapping and timing.]]> Wed, 11 Dec 2024 00:23:11 GMT /slideshow/global-positioning-system-gps-components-and-its-functions-pdf/273977463 kumaresankummu@slideshare.net(kumaresankummu) Global positioning system (GPS), components and its functions.pdf kumaresankummu The Global Positioning System (GPS) is a satellite-based navigation system that provides accurate location, navigation, and timing information worldwide. It consists of three main components: the space segment (satellites orbiting the Earth), the control segment (ground stations that monitor and maintain the satellites), and the user segment (GPS receivers used by individuals and devices). The satellites transmit signals, which are received by GPS receivers to calculate precise positioning. The control segment ensures the accuracy of satellite data, while the user segment interprets this data to determine location. Together, these components enable GPS to support a wide range of applications, from navigation to mapping and timing. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/globalpositioningsystemgpscomponentsanditsfunctions-241211002311-ade671d9-thumbnail.jpg?width=120&height=120&fit=bounds" /> The Global Positioning System (GPS) is a satellite-based navigation system that provides accurate location, navigation, and timing information worldwide. It consists of three main components: the space segment (satellites orbiting the Earth), the control segment (ground stations that monitor and maintain the satellites), and the user segment (GPS receivers used by individuals and devices). The satellites transmit signals, which are received by GPS receivers to calculate precise positioning. The control segment ensures the accuracy of satellite data, while the user segment interprets this data to determine location. Together, these components enable GPS to support a wide range of applications, from navigation to mapping and timing.

Global positioning system (GPS), components and its functions.pdf from Dr. M. Kumaresan

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0 Remote sensing concepts and application in agriculture.pdf /slideshow/remote-sensing-concepts-and-application-in-agriculture-pdf/273976861 remotesensingconceptsandapplicationinagriculture-241210233111-abbb4005
Remote sensing in agriculture involves using satellite or aerial imagery to gather data on crops, soil, and environmental conditions. Applications include monitoring crop health, estimating yields, detecting pests, managing irrigation, and optimizing land use. It enhances precision farming by providing timely, large-scale insights for better decision-making.]]>
Remote sensing in agriculture involves using satellite or aerial imagery to gather data on crops, soil, and environmental conditions. Applications include monitoring crop health, estimating yields, detecting pests, managing irrigation, and optimizing land use. It enhances precision farming by providing timely, large-scale insights for better decision-making.]]> Tue, 10 Dec 2024 23:31:10 GMT /slideshow/remote-sensing-concepts-and-application-in-agriculture-pdf/273976861 kumaresankummu@slideshare.net(kumaresankummu) Remote sensing concepts and application in agriculture.pdf kumaresankummu Remote sensing in agriculture involves using satellite or aerial imagery to gather data on crops, soil, and environmental conditions. Applications include monitoring crop health, estimating yields, detecting pests, managing irrigation, and optimizing land use. It enhances precision farming by providing timely, large-scale insights for better decision-making. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/remotesensingconceptsandapplicationinagriculture-241210233111-abbb4005-thumbnail.jpg?width=120&height=120&fit=bounds" /> Remote sensing in agriculture involves using satellite or aerial imagery to gather data on crops, soil, and environmental conditions. Applications include monitoring crop health, estimating yields, detecting pests, managing irrigation, and optimizing land use. It enhances precision farming by providing timely, large-scale insights for better decision-making.

Remote sensing concepts and application in agriculture.pdf from Dr. M. Kumaresan

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0 Propagation - Asexual - Grafting and budding.pdf /slideshow/propagation-asexual-grafting-and-budding-pdf/272816731 propagation-asexual-graftingandbudding-241028144250-02e54da4
Vegetative propagation – Grafting and Budding]]>
Vegetative propagation – Grafting and Budding]]> Mon, 28 Oct 2024 14:42:50 GMT /slideshow/propagation-asexual-grafting-and-budding-pdf/272816731 kumaresankummu@slideshare.net(kumaresankummu) Propagation - Asexual - Grafting and budding.pdf kumaresankummu Vegetative propagation – Grafting and Budding <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/propagation-asexual-graftingandbudding-241028144250-02e54da4-thumbnail.jpg?width=120&height=120&fit=bounds" /> Vegetative propagation – Grafting and Budding

Propagation - Asexual - Grafting and budding.pdf from Dr. M. Kumaresan

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0 Propagation - Asexual - Cutting and Layering.pdf /slideshow/propagation-asexual-cutting-and-layering-pdf/272816225 propagation-asexual-cuttingandlayering-241028142933-619f7840
Vegetative propagation – Cutting and Layering]]>
Vegetative propagation – Cutting and Layering]]> Mon, 28 Oct 2024 14:29:33 GMT /slideshow/propagation-asexual-cutting-and-layering-pdf/272816225 kumaresankummu@slideshare.net(kumaresankummu) Propagation - Asexual - Cutting and Layering.pdf kumaresankummu Vegetative propagation – Cutting and Layering <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/propagation-asexual-cuttingandlayering-241028142933-619f7840-thumbnail.jpg?width=120&height=120&fit=bounds" /> Vegetative propagation – Cutting and Layering

Propagation - Asexual - Cutting and Layering.pdf from Dr. M. Kumaresan

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0 Horticulture- Introduction - Scope and Importance.pdf /slideshow/horticulture-introduction-scope-and-importance-pdf/272780232 horticulture-introduction-241027153909-45f0db21
Horticulture- Introduction - Scope and Importance.pdf]]>
Horticulture- Introduction - Scope and Importance.pdf]]> Sun, 27 Oct 2024 15:39:08 GMT /slideshow/horticulture-introduction-scope-and-importance-pdf/272780232 kumaresankummu@slideshare.net(kumaresankummu) Horticulture- Introduction - Scope and Importance.pdf kumaresankummu Horticulture- Introduction - Scope and Importance.pdf <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/horticulture-introduction-241027153909-45f0db21-thumbnail.jpg?width=120&height=120&fit=bounds" /> Horticulture- Introduction - Scope and Importance.pdf

Horticulture- Introduction - Scope and Importance.pdf from Dr. M. Kumaresan

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0 Asexual propagation, importance, advantages and disadvantages .pdf /slideshow/asexual-propagation-importance-advantages-and-disadvantages-pdf-ef86/272778038 asexualpropagationimportanceadvantagesanddisadvantages-241027141628-8a46b56e
Asexual propagation, importance, advantages and disadvantages .pdf]]>
Asexual propagation, importance, advantages and disadvantages .pdf]]> Sun, 27 Oct 2024 14:16:28 GMT /slideshow/asexual-propagation-importance-advantages-and-disadvantages-pdf-ef86/272778038 kumaresankummu@slideshare.net(kumaresankummu) Asexual propagation, importance, advantages and disadvantages .pdf kumaresankummu Asexual propagation, importance, advantages and disadvantages .pdf <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/asexualpropagationimportanceadvantagesanddisadvantages-241027141628-8a46b56e-thumbnail.jpg?width=120&height=120&fit=bounds" /> Asexual propagation, importance, advantages and disadvantages .pdf

Asexual propagation, importance, advantages and disadvantages .pdf from Dr. M. Kumaresan

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0 Division and Classification of Horticultural Crops .pdf /slideshow/division-and-classification-of-horticultural-crops-pdf/272467710 divisionandclassificationofhorticulturalcrops-241016141606-2f5faefd
Division and classification of horticultural crops – fruits, vegetables, spices and plantation crops, floriculture, landscaping, ornamental gardening, medicinal and aromatic crops]]>
Division and classification of horticultural crops – fruits, vegetables, spices and plantation crops, floriculture, landscaping, ornamental gardening, medicinal and aromatic crops]]> Wed, 16 Oct 2024 14:16:06 GMT /slideshow/division-and-classification-of-horticultural-crops-pdf/272467710 kumaresankummu@slideshare.net(kumaresankummu) Division and Classification of Horticultural Crops .pdf kumaresankummu Division and classification of horticultural crops – fruits, vegetables, spices and plantation crops, floriculture, landscaping, ornamental gardening, medicinal and aromatic crops <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/divisionandclassificationofhorticulturalcrops-241016141606-2f5faefd-thumbnail.jpg?width=120&height=120&fit=bounds" /> Division and classification of horticultural crops – fruits, vegetables, spices and plantation crops, floriculture, landscaping, ornamental gardening, medicinal and aromatic crops

Division and Classification of Horticultural Crops .pdf from Dr. M. Kumaresan

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0 Propagation - Sexual propagation and dormancy.pdf /slideshow/propagation-sexual-propagation-and-dormancy-pdf/272437794 propagation-sexualpropagationanddormancy-241015165706-8e1c380e
Sexual propagation - Importance, Advantages and Disadvantages - Types of Dormancy - Methods of Enhancement of Seed Viability]]>
Sexual propagation - Importance, Advantages and Disadvantages - Types of Dormancy - Methods of Enhancement of Seed Viability]]> Tue, 15 Oct 2024 16:57:06 GMT /slideshow/propagation-sexual-propagation-and-dormancy-pdf/272437794 kumaresankummu@slideshare.net(kumaresankummu) Propagation - Sexual propagation and dormancy.pdf kumaresankummu Sexual propagation - Importance, Advantages and Disadvantages - Types of Dormancy - Methods of Enhancement of Seed Viability <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/propagation-sexualpropagationanddormancy-241015165706-8e1c380e-thumbnail.jpg?width=120&height=120&fit=bounds" /> Sexual propagation - Importance, Advantages and Disadvantages - Types of Dormancy - Methods of Enhancement of Seed Viability

Propagation - Sexual propagation and dormancy.pdf from Dr. M. Kumaresan

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0 Production Technology of Oil Palm (Elaeis guineensis).pdf /slideshow/production-technology-of-oil-palm-elaeis-guineensis-pdf/272235194 productiontechnologyofoilpalm-241007062653-330a5c45
Oil palm - Climate and soil requirements - varieties - propagation - nursery management - planting and - planting systems - cropping systems - after care - water, nutrient and weed management - intercropping - multi-tier cropping system - mulching - special horticultural practices - maturity indices, harvest and yield - pests and diseases - processing - value addition]]>
Oil palm - Climate and soil requirements - varieties - propagation - nursery management - planting and - planting systems - cropping systems - after care - water, nutrient and weed management - intercropping - multi-tier cropping system - mulching - special horticultural practices - maturity indices, harvest and yield - pests and diseases - processing - value addition]]> Mon, 07 Oct 2024 06:26:53 GMT /slideshow/production-technology-of-oil-palm-elaeis-guineensis-pdf/272235194 kumaresankummu@slideshare.net(kumaresankummu) Production Technology of Oil Palm (Elaeis guineensis).pdf kumaresankummu Oil palm - Climate and soil requirements - varieties - propagation - nursery management - planting and - planting systems - cropping systems - after care - water, nutrient and weed management - intercropping - multi-tier cropping system - mulching - special horticultural practices - maturity indices, harvest and yield - pests and diseases - processing - value addition <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/productiontechnologyofoilpalm-241007062653-330a5c45-thumbnail.jpg?width=120&height=120&fit=bounds" /> Oil palm - Climate and soil requirements - varieties - propagation - nursery management - planting and - planting systems - cropping systems - after care - water, nutrient and weed management - intercropping - multi-tier cropping system - mulching - special horticultural practices - maturity indices, harvest and yield - pests and diseases - processing - value addition

Production Technology of Oil Palm (Elaeis guineensis).pdf from Dr. M. Kumaresan

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0 Production Technology of Coffee (Coffea arabica and C. canephora).pdf /slideshow/production-technology-of-coffee-coffea-arabica-and-c-canephora-pdf/272208351 productiontechnologyofcoffee-241005165639-2713a741
Coffee - Climate and soil requirements - varieties- propagation - nursery management - planting and planting systems - cropping systems- after care- training and pruning - water, nutrient and weed management - shade management - intercropping - mulching - cover cropping - special horticultural practices - maturity indices, harvest and yield - pests and diseases - processing ]]>
Coffee - Climate and soil requirements - varieties- propagation - nursery management - planting and planting systems - cropping systems- after care- training and pruning - water, nutrient and weed management - shade management - intercropping - mulching - cover cropping - special horticultural practices - maturity indices, harvest and yield - pests and diseases - processing ]]> Sat, 05 Oct 2024 16:56:39 GMT /slideshow/production-technology-of-coffee-coffea-arabica-and-c-canephora-pdf/272208351 kumaresankummu@slideshare.net(kumaresankummu) Production Technology of Coffee (Coffea arabica and C. canephora).pdf kumaresankummu Coffee - Climate and soil requirements - varieties- propagation - nursery management - planting and planting systems - cropping systems- after care- training and pruning - water, nutrient and weed management - shade management - intercropping - mulching - cover cropping - special horticultural practices - maturity indices, harvest and yield - pests and diseases - processing <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/productiontechnologyofcoffee-241005165639-2713a741-thumbnail.jpg?width=120&height=120&fit=bounds" /> Coffee - Climate and soil requirements - varieties- propagation - nursery management - planting and planting systems - cropping systems- after care- training and pruning - water, nutrient and weed management - shade management - intercropping - mulching - cover cropping - special horticultural practices - maturity indices, harvest and yield - pests and diseases - processing

Production Technology of Coffee (Coffea arabica and C. canephora).pdf from Dr. M. Kumaresan

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0 https://cdn.slidesharecdn.com/profile-photo-kumaresankummu-48x48.jpg?cb=1736647872 https://cdn.slidesharecdn.com/ss_thumbnails/plantgrowthregulators-growthfloweringandfruiting-241212154650-1c2830c7-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/plant-growth-regulators-growth-flowering-and-fruiting-pdf/274018693 Plant growth regulator... https://cdn.slidesharecdn.com/ss_thumbnails/pollinationfruitsetfruitdropscausesoffruitdropsparthenocarpyandparthenogenesis-241212145303-ee19b250-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/pollination-fruit-set-fruit-drops-causes-of-fruit-drops-parthenocarpy-and-parthenogenesis-pdf/274017837 Pollination, Fruit set... https://cdn.slidesharecdn.com/ss_thumbnails/micro-propagation-241212143936-c290a1ac-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/micro-propagation-culturing-plant-tissues-and-organs/274017534 Micro- Propagation - C...