This document provides an overview of ecology and the biosphere from an introductory ecology textbook. It discusses the following key points in 3 sentences or less:
Ecology is the scientific study of interactions between organisms and their environment. Ecologists study these interactions across different levels from individual organisms to the entire biosphere. The document outlines the different focus areas of ecology including organismal, population, community, ecosystem, landscape, and global ecology.
It then discusses how ecology links to evolutionary biology and informs environmental issues. Various abiotic and biotic factors that influence the distribution of species are examined, including dispersal, behavior, climate, temperature, water, and interactions with other species. Finally, it provides an overview
Ecology is the scientific study of the interactions between organisms and their environment. It was coined in 1866 by German biologist Ernst Haeckel and comes from the Greek words "oikos" meaning house and "logos" meaning study. There are six levels of ecological organization: individual, population, community, ecosystem, biome, and biosphere. Ecology has many branches including plant ecology, animal ecology, human ecology, applied ecology, medical ecology, ecophysiology, functional ecology, and fire ecology. Experts in ecology are called ecologists.
1) Ecology developed as a field of study over thousands of years, with early concepts found in ancient Hindu and Greek texts from 600 BC and 370 BC.
2) In the 18th and 19th centuries, key thinkers like Linnaeus, Darwin, and Humboldt made important contributions relating to biogeography, natural selection, and interactions between organisms and their environment.
3) The term "ecology" was coined by Ernst Haeckel in 1866, and the field expanded in the 20th century with pioneering work by Shelford, Elton, Tansley, and Eugene Odum on concepts like food webs, ecosystems, and ecosystem ecology.
Ecology is the study of the relationships between organisms and their environment. It examines biotic factors like other organisms as well as abiotic factors such as climate and geology. Organisms interact with their environment through a process of action, reaction, and coaction. Action refers to how the environment affects organisms, reaction is how organisms affect the environment, and coaction is how organisms interact with each other. Ecology also examines human communities and how they relate to and depend upon their surrounding environment.
Barry Commoner was an American biologist and environmentalist who is credited as a founder of the modern environmental movement. He was famous for his public campaigns against nuclear testing, chemical pollution, and environmental decay. Commoner summarized the basic principles of ecology into what he termed the "Four Laws of Ecology": 1) Everything is connected to everything else, 2) There is strength and stability in the unity of differences, 3) Consumption must not exceed production, and 4) Everything has a purpose. These laws explain the relationships and interdependencies found in communities and ecosystems and that humankind is dependent on the characteristics of the land.
The document traces the history and development of ecology from its early roots in the 18th century through present day. It discusses key figures like Carl Linnaeus, Alexander von Humboldt, Charles Darwin, and others and their contributions to establishing ecology as a recognized scientific discipline. Major developments included the establishment of biogeography, the ecosystem concept, succession theory, and recognition of humans as an ecological factor. Conservation efforts also stemmed from the growing field of ecology.
Ecology is the scientific study of the interactions between organisms and their environment. It was coined in 1866 by Ernst Haeckel from the Greek words "oikos" meaning house or environment, and "logos" meaning study. Ecology studies the distribution and abundance of organisms and the interactions between organisms and their physical and biological environment. It examines these relationships at different levels of organization from organisms to ecosystems. Ecology is important for understanding how to maintain a healthy biosphere and sustainable use of natural resources through principles of conservation.
Ecology has a complex origin dating back to ancient Greek philosophers like Aristotle who made early observations of natural history. Modern ecology emerged in the late 19th century as a more rigorous science. Key figures included Ernst Haeckel who coined the term "ecology" and Charles Darwin whose theory of evolution was a cornerstone of ecological thought. Ecology is defined as the scientific study of the interactions between organisms and their environment, and includes variables like species distribution, abundance, and changing states within ecosystems. It is a multidisciplinary field with applications in conservation, natural resource management, and human social systems.
This document provides an introduction to key concepts in ecology. It defines ecology as the study of the relationships between organisms and their environment. It describes the different levels of ecological organization from the biosphere down to individual organisms. It explains that all organisms interact with and depend on other living and non-living things in their environment. It also outlines biotic and abiotic factors that influence organisms, adaptations that help organisms survive, and mechanisms like acclimation, dormancy, and migration that aid survival. Finally, it defines niche and biogeography.
Ecology is the scientific study of the interactions between organisms and their environment. It was coined in 1866 by German biologist Ernst Haeckel and comes from the Greek words "oikos" meaning house and "logos" meaning study. There are six levels of ecological organization: individual, population, community, ecosystem, biome, and biosphere. Ecology has many branches including plant ecology, animal ecology, human ecology, applied ecology, medical ecology, ecophysiology, functional ecology, and fire ecology. Experts in ecology are called ecologists.
1) Ecology developed as a field of study over thousands of years, with early concepts found in ancient Hindu and Greek texts from 600 BC and 370 BC.
2) In the 18th and 19th centuries, key thinkers like Linnaeus, Darwin, and Humboldt made important contributions relating to biogeography, natural selection, and interactions between organisms and their environment.
3) The term "ecology" was coined by Ernst Haeckel in 1866, and the field expanded in the 20th century with pioneering work by Shelford, Elton, Tansley, and Eugene Odum on concepts like food webs, ecosystems, and ecosystem ecology.
Ecology is the study of the relationships between organisms and their environment. It examines biotic factors like other organisms as well as abiotic factors such as climate and geology. Organisms interact with their environment through a process of action, reaction, and coaction. Action refers to how the environment affects organisms, reaction is how organisms affect the environment, and coaction is how organisms interact with each other. Ecology also examines human communities and how they relate to and depend upon their surrounding environment.
Barry Commoner was an American biologist and environmentalist who is credited as a founder of the modern environmental movement. He was famous for his public campaigns against nuclear testing, chemical pollution, and environmental decay. Commoner summarized the basic principles of ecology into what he termed the "Four Laws of Ecology": 1) Everything is connected to everything else, 2) There is strength and stability in the unity of differences, 3) Consumption must not exceed production, and 4) Everything has a purpose. These laws explain the relationships and interdependencies found in communities and ecosystems and that humankind is dependent on the characteristics of the land.
The document traces the history and development of ecology from its early roots in the 18th century through present day. It discusses key figures like Carl Linnaeus, Alexander von Humboldt, Charles Darwin, and others and their contributions to establishing ecology as a recognized scientific discipline. Major developments included the establishment of biogeography, the ecosystem concept, succession theory, and recognition of humans as an ecological factor. Conservation efforts also stemmed from the growing field of ecology.
Ecology is the scientific study of the interactions between organisms and their environment. It was coined in 1866 by Ernst Haeckel from the Greek words "oikos" meaning house or environment, and "logos" meaning study. Ecology studies the distribution and abundance of organisms and the interactions between organisms and their physical and biological environment. It examines these relationships at different levels of organization from organisms to ecosystems. Ecology is important for understanding how to maintain a healthy biosphere and sustainable use of natural resources through principles of conservation.
Ecology has a complex origin dating back to ancient Greek philosophers like Aristotle who made early observations of natural history. Modern ecology emerged in the late 19th century as a more rigorous science. Key figures included Ernst Haeckel who coined the term "ecology" and Charles Darwin whose theory of evolution was a cornerstone of ecological thought. Ecology is defined as the scientific study of the interactions between organisms and their environment, and includes variables like species distribution, abundance, and changing states within ecosystems. It is a multidisciplinary field with applications in conservation, natural resource management, and human social systems.
This document provides an introduction to key concepts in ecology. It defines ecology as the study of the relationships between organisms and their environment. It describes the different levels of ecological organization from the biosphere down to individual organisms. It explains that all organisms interact with and depend on other living and non-living things in their environment. It also outlines biotic and abiotic factors that influence organisms, adaptations that help organisms survive, and mechanisms like acclimation, dormancy, and migration that aid survival. Finally, it defines niche and biogeography.
The document provides information about ecology, including:
1) Ecology is defined as the study of interrelationships between organisms and their environment. It examines how organisms interact with each other and their habitat.
2) Ecology can be studied at different levels, including the individual, population, community, ecosystem, and biome. Key components of ecosystems include biotic factors like producers, consumers, and decomposers, as well as abiotic factors such as climate, soil, and sunlight.
3) Natural ecosystems include terrestrial ecosystems like forests and grasslands, as well as aquatic ecosystems such as freshwater and marine systems. Artificial ecosystems are influenced by human activity like agriculture.
In this persentation I give a short description about ecology and the history of it. I also show the ecological crisis as well as environmental situation for ethical and social awareness.
The document provides an overview of key concepts in ecology, including:
1) It describes five levels of ecological organization from the biosphere level down to the individual organism level.
2) It explains the interdependence between organisms and their environment and how ecological models are used to study these relationships.
3) It discusses important ecological concepts such as producers, consumers, trophic levels, biogeochemical cycles, and energy flow through ecosystems.
This document discusses the impact of science on society. It notes that while science has helped solve major problems through fields like technology, agriculture and medicine, the rapid development of science also comes with environmental and resource issues like pollution, degradation and depletion. The document concludes that in applying science, we must consider the welfare of the environment as a primary concern to avoid science itself becoming a problem.
The document provides an overview of ecology, discussing key concepts like ecology scales, the ten rules of ecology, adaptations, niches, biogeochemical cycles, trophic structure, energy flow, food webs, community structure and stability, competition, predation, succession. It covers these concepts across multiple levels from individuals to ecosystems.
History of insect ecology and components of environmentManish pal
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The document provides a history of insect ecology, beginning with Ernst Haeckel coining the term "ecology" in 1869. Some important early contributors included Antonie van Leeuwenhoek in the 1600s, who developed concepts of food chains and population regulation, and Charles Darwin in the 1800s, who established the theory of evolution by natural selection. Foundations of modern ecology emerged in the early 1900s through the work of plant and animal physiologists studying insect environments and factors like climate, temperature, and humidity. Key developments in insect ecology concepts and models occurred throughout the 1900s, including works on niches, habitats, and predator-prey relationships. Modern insect ecology analyzes both abiotic environmental
Ecology is the scientific study of organisms `at home' which is called as the `environment'. The term `environment' refers to those parts of the world or the total set of circumstances which surround an organism or a group of organisms.
This document provides an overview of key concepts in ecology and environmental biology, including:
1) It defines ecology as the scientific study of interactions between organisms and their environment.
2) It describes producers, consumers, food chains, food webs, and trophic levels within ecosystems.
3) It explains ecological pyramids and how energy and biomass decrease at higher trophic levels.
4) It outlines ecological interactions like competition, predation, and the three types of symbiosis - mutualism, commensalism, and parasitism.
An ecosystem is defined as the interaction between living and non-living components in a given area. It includes all living organisms such as plants, animals, and bacteria, as well as non-living factors like water, soil, climate, and weather. The structure of an ecosystem describes its organisms and physical features, and is made up of abiotic factors such as soil, water, and minerals, as well as biotic factors like plants, animals, and fungi. Some examples of ecosystems include deserts, forests, hills, ponds, and aquatic environments.
Ecology is defined as the science that studies the interactions between organisms and their environment. The term comes from the Greek words "oikos" meaning house or habitation, and "logos" meaning discourse or study. It deals with how organisms live in their environments and interact with biotic factors like other living things as well as abiotic factors such as climate. Ecosystems form through the complex interactions between biotic and abiotic components, with energy flowing in one direction and biogeochemical cycles regulating chemicals. Ecology has many applications and branches including applied ecology, population ecology, limnology, and human ecology.
There are several aspects in which the components of geography and ecology are similar in their concepts and applications.
In several areas, these two subjects also go hand-in-hand.
Geography and ecology are related to each other. An understanding of ecology and its relation with geography is needed. This module explains their inter-relationships.
1. The document provides information about various types of ecosystems including terrestrial, aquatic, forest, grassland, desert, pond, lake, marine and ocean ecosystems.
2. It describes the key components of an ecosystem as biotic factors (living organisms) and abiotic factors (non-living physical components).
3. Energy flows through ecosystems via food chains and food webs with plants at the base converting solar energy to chemical energy which is then transferred between trophic levels.
Ecology is the study of interactions between organisms and their environment. It examines how living things affect each other and the world they inhabit. Ecologists study these interactions across different levels of organization, from individual organisms and populations, to biological communities within ecosystems, and finally the biosphere - the global region that supports life. Abiotic factors like temperature and biotic factors such as other living things both shape organisms and their development.
Introduction to environment ecology &ecosystemApurva Sanghani
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1) Environment refers to all the biological and nonbiological factors surrounding and affecting an organism. It includes biotic (living) and abiotic (non-living) components that interact in a dynamic system.
2) Ecology is the study of the relationships between organisms and their environment. It has two main divisions - autecology which studies individual species, and synecology which examines the interactions within and between communities.
3) An ecosystem is the functional unit of ecology comprising biotic and abiotic components that interact through food chains, food webs, and biogeochemical cycles. Energy and matter are transferred between ecosystem components in both directions.
An ecosystem is defined as a biological community of interacting organisms and their physical environment. It includes both biotic factors such as plants, animals, fungi and bacteria, as well as abiotic nonliving factors like climate, soil and rocks. Within an ecosystem, organisms live in a habitat and often have symbiotic relationships where they live closely and benefit from one another.
This document defines an ecosystem and its components. An ecosystem is a community of living organisms that interact with non-living elements in their environment. It has biotic components, which are the living organisms, and abiotic components, which are non-living elements like climate, soil, water and nutrients. The biotic components are classified into producers, consumers and decomposers based on how they obtain food. Producers like plants produce their own food through photosynthesis. Consumers eat other organisms for food and are divided into primary, secondary and tertiary consumers. Decomposers break down dead organisms and release nutrients. Ecological succession is the process where one community replaces another over time until a stable community develops in
Ecology is the scientific study of interactions between organisms and their environment. The components of ecology include abiotic (non-living) factors like temperature and biotic (living) factors like other organisms. A niche describes an organism's role and interactions within its ecosystem, including how it meets its needs. Relationships between organisms in an ecosystem can be symbiotic like mutualism, or involve one organism benefiting more than the other like parasitism or commensalism. Natural selection leads to evolution as organisms with traits better suited to their environment are more likely to survive and pass on those traits, changing the gene frequency in a population over time. Speciation occurs when reproductive isolation splits one species into two distinct species.
The document provides information about ecology, including:
1) Ecology is defined as the study of interrelationships between organisms and their environment. It examines how organisms interact with each other and their habitat.
2) Ecology can be studied at different levels, including the individual, population, community, ecosystem, and biome. Key components of ecosystems include biotic factors like producers, consumers, and decomposers, as well as abiotic factors such as climate, soil, and sunlight.
3) Natural ecosystems include terrestrial ecosystems like forests and grasslands, as well as aquatic ecosystems such as freshwater and marine systems. Artificial ecosystems are influenced by human activity like agriculture.
In this persentation I give a short description about ecology and the history of it. I also show the ecological crisis as well as environmental situation for ethical and social awareness.
The document provides an overview of key concepts in ecology, including:
1) It describes five levels of ecological organization from the biosphere level down to the individual organism level.
2) It explains the interdependence between organisms and their environment and how ecological models are used to study these relationships.
3) It discusses important ecological concepts such as producers, consumers, trophic levels, biogeochemical cycles, and energy flow through ecosystems.
This document discusses the impact of science on society. It notes that while science has helped solve major problems through fields like technology, agriculture and medicine, the rapid development of science also comes with environmental and resource issues like pollution, degradation and depletion. The document concludes that in applying science, we must consider the welfare of the environment as a primary concern to avoid science itself becoming a problem.
The document provides an overview of ecology, discussing key concepts like ecology scales, the ten rules of ecology, adaptations, niches, biogeochemical cycles, trophic structure, energy flow, food webs, community structure and stability, competition, predation, succession. It covers these concepts across multiple levels from individuals to ecosystems.
History of insect ecology and components of environmentManish pal
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The document provides a history of insect ecology, beginning with Ernst Haeckel coining the term "ecology" in 1869. Some important early contributors included Antonie van Leeuwenhoek in the 1600s, who developed concepts of food chains and population regulation, and Charles Darwin in the 1800s, who established the theory of evolution by natural selection. Foundations of modern ecology emerged in the early 1900s through the work of plant and animal physiologists studying insect environments and factors like climate, temperature, and humidity. Key developments in insect ecology concepts and models occurred throughout the 1900s, including works on niches, habitats, and predator-prey relationships. Modern insect ecology analyzes both abiotic environmental
Ecology is the scientific study of organisms `at home' which is called as the `environment'. The term `environment' refers to those parts of the world or the total set of circumstances which surround an organism or a group of organisms.
This document provides an overview of key concepts in ecology and environmental biology, including:
1) It defines ecology as the scientific study of interactions between organisms and their environment.
2) It describes producers, consumers, food chains, food webs, and trophic levels within ecosystems.
3) It explains ecological pyramids and how energy and biomass decrease at higher trophic levels.
4) It outlines ecological interactions like competition, predation, and the three types of symbiosis - mutualism, commensalism, and parasitism.
An ecosystem is defined as the interaction between living and non-living components in a given area. It includes all living organisms such as plants, animals, and bacteria, as well as non-living factors like water, soil, climate, and weather. The structure of an ecosystem describes its organisms and physical features, and is made up of abiotic factors such as soil, water, and minerals, as well as biotic factors like plants, animals, and fungi. Some examples of ecosystems include deserts, forests, hills, ponds, and aquatic environments.
Ecology is defined as the science that studies the interactions between organisms and their environment. The term comes from the Greek words "oikos" meaning house or habitation, and "logos" meaning discourse or study. It deals with how organisms live in their environments and interact with biotic factors like other living things as well as abiotic factors such as climate. Ecosystems form through the complex interactions between biotic and abiotic components, with energy flowing in one direction and biogeochemical cycles regulating chemicals. Ecology has many applications and branches including applied ecology, population ecology, limnology, and human ecology.
There are several aspects in which the components of geography and ecology are similar in their concepts and applications.
In several areas, these two subjects also go hand-in-hand.
Geography and ecology are related to each other. An understanding of ecology and its relation with geography is needed. This module explains their inter-relationships.
1. The document provides information about various types of ecosystems including terrestrial, aquatic, forest, grassland, desert, pond, lake, marine and ocean ecosystems.
2. It describes the key components of an ecosystem as biotic factors (living organisms) and abiotic factors (non-living physical components).
3. Energy flows through ecosystems via food chains and food webs with plants at the base converting solar energy to chemical energy which is then transferred between trophic levels.
Ecology is the study of interactions between organisms and their environment. It examines how living things affect each other and the world they inhabit. Ecologists study these interactions across different levels of organization, from individual organisms and populations, to biological communities within ecosystems, and finally the biosphere - the global region that supports life. Abiotic factors like temperature and biotic factors such as other living things both shape organisms and their development.
Introduction to environment ecology &ecosystemApurva Sanghani
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1) Environment refers to all the biological and nonbiological factors surrounding and affecting an organism. It includes biotic (living) and abiotic (non-living) components that interact in a dynamic system.
2) Ecology is the study of the relationships between organisms and their environment. It has two main divisions - autecology which studies individual species, and synecology which examines the interactions within and between communities.
3) An ecosystem is the functional unit of ecology comprising biotic and abiotic components that interact through food chains, food webs, and biogeochemical cycles. Energy and matter are transferred between ecosystem components in both directions.
An ecosystem is defined as a biological community of interacting organisms and their physical environment. It includes both biotic factors such as plants, animals, fungi and bacteria, as well as abiotic nonliving factors like climate, soil and rocks. Within an ecosystem, organisms live in a habitat and often have symbiotic relationships where they live closely and benefit from one another.
This document defines an ecosystem and its components. An ecosystem is a community of living organisms that interact with non-living elements in their environment. It has biotic components, which are the living organisms, and abiotic components, which are non-living elements like climate, soil, water and nutrients. The biotic components are classified into producers, consumers and decomposers based on how they obtain food. Producers like plants produce their own food through photosynthesis. Consumers eat other organisms for food and are divided into primary, secondary and tertiary consumers. Decomposers break down dead organisms and release nutrients. Ecological succession is the process where one community replaces another over time until a stable community develops in
Ecology is the scientific study of interactions between organisms and their environment. The components of ecology include abiotic (non-living) factors like temperature and biotic (living) factors like other organisms. A niche describes an organism's role and interactions within its ecosystem, including how it meets its needs. Relationships between organisms in an ecosystem can be symbiotic like mutualism, or involve one organism benefiting more than the other like parasitism or commensalism. Natural selection leads to evolution as organisms with traits better suited to their environment are more likely to survive and pass on those traits, changing the gene frequency in a population over time. Speciation occurs when reproductive isolation splits one species into two distinct species.
Epidemiology is the study of disease patterns in human populations and the factors that influence health. It involves measuring disease frequency, investigating causes, and controlling health problems. The goals of epidemiology are to understand and reduce the burden of disease in society. Key aspects include describing disease distribution, identifying risk factors, and evaluating interventions. The history of epidemiology began with early physicians like Hippocrates and made advances through pioneers such as John Graunt, William Farr, and John Snow, who conducted seminal studies linking disease to environmental factors. Epidemiology now covers a wide range of fields and plays an important role in public health.
This document discusses the role of individuals in preserving natural resources. It defines natural resources and classifies them based on origin (biotic vs abiotic) and availability (renewable vs non-renewable). Some key natural resources mentioned are forests, water, minerals, food, land, and energy. The document then outlines various measures individuals can take to conserve forests (e.g. controlled deforestation and planting trees), water (e.g. reducing usage and pollution), minerals (e.g. recycling and substitution), food/land (e.g. organic farming and preventing erosion), and energy (e.g. efficient appliances and insulation). It stresses the importance of sustainability and responsibility of individuals and governments to preserve
The effect of technology on today's society pptoacore
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The document discusses the effects of modern technology on today's society. It notes that while technology allows people to meet and communicate over long distances, it can also isolate people, change behaviors and attitudes, and in some cases harm people. The document includes several polls that show most people depend on technology to some degree but have mixed views on whether advances are necessary or if social networks are needed. It concludes with a quote about using technology advances to increase efficiency without being burdened by new processes.
This document discusses the key concepts of ecology at different levels of organization. It begins by defining ecology and its main subdisciplines: global ecology examines interactions across the biosphere, landscape ecology focuses on exchanges between ecosystems, ecosystem ecology emphasizes energy flow within communities, population ecology examines factors affecting population sizes, and organismal ecology studies how individuals meet environmental challenges. It then covers various abiotic factors that influence species distributions, including temperature, water, sunlight, and geological features. Biotic interactions like competition and predation also shape where organisms can survive.
Ecology is the scientific study of interactions between organisms and their environment. These interactions determine species distributions and abundances. Ecologists use observations and experiments to understand why species are distributed and abundant as they are. Key factors include climate, habitat, resources, and interactions with other species. Ecosystems consist of all organisms in a community along with their abiotic environment. Energy flows through ecosystems while matter cycles within them. Primary producers convert light energy to chemical energy, which is then transferred through food webs to consumers and decomposers.
The document describes the key concepts in biology covered in Chapter 1 of Biology: Concepts & Connections. It discusses the following main points:
1) Biology is the study of life and covers different levels of organization from molecules to ecosystems.
2) Scientists use two approaches - discovery science and hypothesis-driven science using the scientific method.
3) All life can be classified into three domains based on cell structure and genetics.
4) Despite diversity, all life shares common features like cells, DNA, and the ability to evolve through natural selection.
5) Organisms interact in complex webs within ecosystems, with energy and nutrients cycling between living and nonliving parts.
This document provides an overview of Charles Darwin's theory of evolution by natural selection. It discusses key figures and findings that influenced Darwin's thinking, such as Linnaeus' taxonomy, Lamarck's theory of inheritance of acquired traits, and Lyell and Hutton's theories of gradual geological change. The document also summarizes Darwin's two main ideas in Origin of Species: that evolution explains life's diversity and unity, and that natural selection is a mechanism of adaptive evolution. It provides examples of natural selection in action and evidence that supports evolution, such as molecular homologies and transitional fossils.
This document provides an overview of the field of ecology, including its various subfields and how they study interactions between organisms and their environments. It discusses how ecology integrates areas of biological research and informs environmental decision making. It also summarizes how biotic and abiotic factors influence the distribution of species and structure of different biomes, with aquatic biomes covering most of the Earth's surface and climate being important in determining terrestrial biomes.
This seminar presentation discusses the impact of climate change on biodiversity. It begins with an overview of how to manage Earth's temperature through solar energy and greenhouse gases. It then examines worldwide carbon emissions over time and explains the greenhouse effect. The values of biodiversity are outlined, and the presentation shows the impact of climate change on forests visible from space. A case study examines the effect of climate change on mountain pine beetles. The main impacts of climate change discussed are species extinction, effects on forests, water, polar regions and wildlife. The presentation concludes that temperatures will continue to rise and growing seasons will lengthen.
The document discusses the key levels that ecologists study when examining how organisms interact with their environments, including the organism, population, community, and ecosystem levels. It also describes several major biomes found on Earth, including terrestrial, freshwater, and marine biomes. Specifically, it outlines the abiotic and biotic factors that shape communities within different ocean zones, such as the intertidal zone, pelagic zone, benthic zone, photic zone, and aphotic zone. It also discusses how climate influences the distribution of terrestrial communities globally.
Biology - Chp 6 - Humans In The Biosphere - PowerPointMel Anthony Pepito
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This chapter discusses how human activities affect the biosphere and its resources. It covers topics like renewable and nonrenewable resources, including soil, forests, fisheries, air, and freshwater. It also addresses the importance of biodiversity and the threats it faces from habitat loss, pollution, invasive species, and more. The chapter explores the issues of ozone depletion and global climate change, and how understanding these problems helps chart a more sustainable course for managing the biosphere in the future.
This document summarizes key concepts from Chapter 55 of Biology, Seventh Edition regarding conservation biology and restoration ecology. It discusses how conservation biology aims to conserve biodiversity by integrating various fields of study. It also explains how restoration ecology applies ecological principles to return degraded ecosystems to more natural states. The document then covers threats to biodiversity like habitat destruction and introduced species, as well as approaches to conserving populations, landscapes, and ecosystems.
Climate like any other physical phenomena it is dynamic and not static.
In every part of the world one year, one decade or one century is different than the other.
The change does not only have academic important but its effects in all the forms of life.
Plants, animals, human beings change with changes of climate.
In general, all living species thrive under definite and limit conditions and any great deviation from that will leads to destruction and death of the species.
Ecology: Scientific study of interactions between organisms and their environments which includes Biotic Factors: (Living organisms) , Abiotic Factors: (Nonliving physical and chemical conditions of an environment).
What are the levels of the Ecology?
Ecology has Five Levels.
Individual organism: Single organism in an environment
Populations: Group of individual organisms of same species living in the same area
Communities: All of the organisms that inhabit a particular area make up a community, like coral reef and other organisms live around in the reef
Ecosystems: An ecosystem includes both the biotic and abiotic factors of an area
Biosphere:
Sum of all of Earth's ecosystems, it is an envelope of air, land, and water supporting all living things on Earth. It consists of both the atmosphere and ocean.
Ecologists investigate global issues in the biosphere, including climate change and its effect on living things
The effects have been most dramatic at high latitudes, where multiple processes contribute to decreased surface reflectivity
Changes in temperature are causing species to shift their natural ranges; however, those are unable to move in line with changing temperatures are being put at risk.
This document provides an overview of Chapter 26 from Campbell and Reece's Biology textbook, which discusses the evolution of life on Earth and the development of biological diversity. The key points covered include:
1) Early conditions on Earth allowed for the origin of simple life forms, and over billions of years geological events drove the evolution of more complex organisms as life adapted to changing environments.
2) The fossil record provides evidence of major extinction events that wiped out most species, as well as periods where new phyla developed as life radiated into vacant niches.
3) Prokaryotes were the first life forms and influenced the atmosphere through the evolution of oxygen-producing photosynthesis. Eukaryotic cells later
This study examined the relationship between climate change and air quality by reviewing previous research. The study began by dividing the topic into sub-topics and formulating research questions. Answers were found by searching earlier articles related to climate change, air quality, and ozone layer depletion. The results provided information on the causes of climate change, its impacts on factors like sea level and species, and potential solutions like emissions reductions. The study concluded by gaining knowledge on how atmospheric composition is changing and the economic effects of climate change.
An ecosystem consists of organisms living in a community and interacting with abiotic factors. Ecosystems range in size from small aquariums to large forests. Regardless of size, ecosystems involve two main processes - energy flow and chemical cycling. Ecologists view ecosystems as transformers of energy and processors of matter, with energy flowing through while matter cycles within. Primary producers like plants convert light energy to chemical energy, which is then consumed and passed between trophic levels in an ecosystem.
The document discusses ecosystems and communities, including the factors that influence ecosystems such as climate, biotic and abiotic factors, and community interactions like competition, predation, and symbiosis. It also describes ecological succession and the major land biomes.
This chapter discusses cycles and patterns in the biosphere. It explains key concepts like biogeochemical cycles of elements like carbon and oxygen through the biosphere. Food chains are described as the passage of energy from producers to consumers. The natural distribution of biota is influenced by evolutionary development, migration, reproductive success, and environmental relationships with factors like climate and topography.
This document provides definitions and overview information about the environment and environmental studies. It defines environment as the sum of surrounding conditions, including both biotic and abiotic factors, that influence living organisms. Environmental science is described as the interdisciplinary study of how living things interact with each other and their non-living surroundings. The key components of the environment - the atmosphere, hydrosphere, lithosphere, and biosphere - are also summarized. The document then discusses the relationship between humans and the environment and the impacts of technology before concluding with summaries of environmental degradation and sustainable development.
This document provides an overview of ecosystems and biomes. It begins by defining an ecosystem as a group of organisms along with their physical environment. Ecosystems are made up of biotic (living) and abiotic (non-living) factors. Biodiversity, or the variety of species in an ecosystem, determines how resilient the ecosystem is to change. Ecosystems go through successional changes over long periods of time as the environment and communities change. There are three main types of terrestrial biomes - tropical, temperate, and high-latitude - determined by factors like latitude and climate. Aquatic ecosystems include freshwater, wetlands, estuaries, and marine environments. The document concludes with a discussion of levels
Mening, Nature and Components Of EnvironmentMudAssar IQbal
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The document discusses the meaning, nature, and components of the environment. It defines environment as the natural surroundings that directly or indirectly influence the growth and development of organisms. The environment is classified into physical, biological, and cultural components. The physical environment includes the atmosphere, hydrosphere, and lithosphere. The biological environment includes flora, fauna, and microbes. The cultural environment refers to learned behavioral traits shared within a society. Components are further divided into biotic (living) and abiotic (physical) factors. Biotic components include producers, consumers, and decomposers, while abiotic components are climatic (water, air) and edaphic (land).
This document provides an introduction to the topic of ecological equilibrium. It defines key terms like ecosystem, biotic and abiotic factors, habitat, niche, and ecology. It discusses the main divisions of ecology and objectives of studying ecology, which include understanding dynamics of surroundings and conserving the environment. The three pillars of sustainability - economic, social, and environmental development - are explained. The concepts of ecological balance, balance of nature, and ecosystem stability are introduced. Finally, issues affecting ecological equilibrium like climatic, topographic, edaphic, biotic factors and limiting factors are outlined.
This document provides information about the monocotyledonous flowering plants, or monocots. It discusses their defining characteristics and classification. Specifically, it describes the monocot orders Alismatales, Arecales, Zingiberales, and Poales. For each order, it lists the included families and provides details about their morphological features and economically important species. Images are included to illustrate various monocot structures and taxa. The document is an informative overview of monocot diversity and systematics.
Gregor Mendel conducted experiments breeding pea plants that varied in traits like flower color. By carefully tracking the inheritance of traits over generations, he discovered two laws of heredity: segregation and independent assortment. Mendel found that traits separate, or segregate, so offspring receive one allele for each trait from each parent. He also found that different traits assort independently, resulting in unpredictable combinations in offspring. Mendel's laws explained the patterns of inheritance he observed, like the 3:1 ratio of dominant to recessive traits in the second filial generation. His work established the foundations of classical genetics.
Evolution of plants and non vascular.pptxJasper Obico
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1. The document provides an overview of the evolution of plants, beginning with aquatic algae like Elodea and Charales that reproduced through isogamy or oogamy, and the first land plants like mosses, liverworts, and hornworts that have alternation of generations with a haploid gametophyte and diploid sporophyte generation.
2. It describes key characteristics of bryophytes like mosses, liverworts, and hornworts including their sexual reproduction through archegonia and antheridia and asexual reproduction through spores.
3. The life cycles of model bryophytes like Marchantia, Sphagnum moss,
The document contains notes from botany lectures covering various topics:
1. It defines key terms like dichlamydeous and homochlamydeous related to flower structure.
2. It describes the development of flowers from initiation through organ formation in Arabidopsis thaliana.
3. It provides diagrams and explanations of the structure and function of stamens, carpels, and the male gametophyte.
4. It compares the differences between carpels, pistils, and gynoecium and discusses the advantages of closed carpels in angiosperms.
This document provides an overview of the eudicots, which are characterized by tricolpate or tricolpate-derived pollen grains. It discusses the major orders of core eudicots including Ranunculales, Caryophyllales, Saxifragales, rosids, and asterids. Specific families are highlighted such as Myrtaceae, Fabaceae, and the three subfamilies within Fabaceae. Diagrams are included to illustrate floral characteristics of various plants within these groups.
This document provides information about flowering plant diversity and classification, focusing on the order Asterids. It discusses the characteristics of the Asterids, including unitegmic ovules that are tenuinucellate. It then lists several orders within the Asterids, including the Cornales, Ericales, Gentianales, Lamiales, Solanales, and more. For each order, it provides the included families. The document also provides more detailed descriptions of characteristics for several economically and medicinally important families, including Apocynaceae, Rubiaceae, Lamiaceae, Solanaceae, and Asteraceae.
- Lycophytes were some of the earliest land plants and include club mosses, spike mosses, and quillworts. They produce spores through sporophylls, which are modified leaves containing sporangia. Most lycophytes are homosporous, producing one type of spore.
- Seedless vascular plants evolved to have two types of vascular tissue - xylem and phloem. Xylem transports water and minerals through dead tracheid cells, while phloem transports sugars and other organic compounds through living cells. Roots evolved from subterranean stems to anchor plants and absorb water and nutrients from the soil. Leaves evolved from stem outgrowths to increase
The document discusses the flow of genetic information from DNA to protein. It describes how DNA contains the genetic code in the form of nucleotide sequences. During transcription, DNA directs the synthesis of messenger RNA (mRNA). Translation then uses the mRNA to synthesize polypeptides through the ribosome. George Beadle and Edward Tatum provided evidence supporting the "one gene-one enzyme" hypothesis through experiments with bread mold mutants. Their work showed that each gene directs the production of a specific enzyme.
1. The document discusses the evolution of plants, beginning with descriptions of Elodea cell structures like chloroplasts and amyloplasts.
2. It then covers the life cycles of plants like Elodea, which alternate between haploid gametophyte and diploid sporophyte generations. This is known as the alternation of generations.
3. Several groups of early land plants are introduced, including bryophytes like liverworts, hornworts and mosses. Details of structures like archegonia and antheridia in reproduction are provided.
This document discusses the evolution and diversity of vascular plants. It defines key characteristics of tracheophytes, including vascular tissue, supportive tissue, roots and shoots. It describes lignin and secondary cell walls. It discusses the alternation of generations life cycle and key plant tissues/structures like xylem, phloem, sclerenchyma and fibers. The document outlines the major groups of vascular plants including rhyniophytes, lycopodiophytes, and euphyllophytes. It provides examples of extant lycophytes like club mosses, spike mosses and quillworts.
1. The document discusses the evolution of plants from algae to land plants. It describes key events in plant evolution including the development of cells, chloroplasts, and alternation of generations with separate haploid gametophyte and diploid sporophyte phases.
2. Details are provided on the structure and reproduction of major plant groups including bryophytes (liverworts, hornworts, and mosses). Liverworts and mosses are described as having both haploid gametophyte and diploid sporophyte generations.
3. Diagrams illustrate the life cycles and reproductive structures of bryophytes and how they differ from vascular land plants in their alternation of generations and lack
This document discusses reproductive structures in flowering plants. It describes the parts of a flower including sepals, petals, stamens, and pistils. It discusses floral variation in terms of complete/incomplete and perfect/imperfect flowers. It also discusses the development of male and female gametophytes, pollination, seed formation, seed dormancy, germination, and fruit formation providing protection and dispersal of seeds. Fruits are classified based on their developmental origin and texture. Seed and fruit dispersal methods include wind, physical expulsion, animal ingestion, attachment to animals, water, and ants.
This document summarizes the key plant organs - meristems, roots, stems, and leaves. It describes the tissues and growth patterns of each organ. Apical and lateral meristems are responsible for primary and secondary growth, respectively. Roots anchor the plant and absorb water/minerals, having root hairs, a root cap, and tissues like the epidermis, cortex, and stele. Stems support leaves and transport fluids, with tissues like the epidermis, vascular bundles, and pith. Leaves undergo photosynthesis, with tissues such as the epidermis, mesophyll, and veins. Leaf shapes, venation patterns, and arrangements vary between plant types and environments.
This document discusses the key concepts and components of systematics, which includes taxonomy and phylogeny. It covers topics such as:
- The goal of phylogenetic reconstruction and evolutionary history.
- The major parts of systematics including description, classification, nomenclature, and identification.
- Tools for communicating taxonomic information such as keys and scientific names.
- Methods for determining evolutionary relationships including cladistics and cladograms.
- Principles of formal taxonomic naming and types of specimens.
- Uses of keys to identify unknown taxa.
This document discusses key concepts in biological evolution and taxonomy. It defines natural theology as the study of nature to understand the creator's plan. It describes the work of Carolus Linnaeus in establishing taxonomy and Jean Baptiste Lamarck's comparison of current and fossil species. The document then covers Darwin and Wallace's theory of descent with modification through natural selection and genetic inheritance. It discusses populations, species, and mechanisms of evolution like genetic drift, mutation, gene flow and natural selection. Finally, it summarizes population genetics, speciation, phylogeny, cladistics, and allopatric versus sympatric speciation.
Plant growth and development [compatibility mode]Jasper Obico
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Plant growth and development involves irreversible increases in size through cell division and enlargement (growth) as well as the progressive changes that elaborate the organism's form (development). Plants require carbon, hydrogen, oxygen, nitrogen, phosphorus, potassium, calcium, magnesium, and other essential nutrients for growth, development, and completing their life cycle. Nutrients are classified as macronutrients, which are required in large amounts, or micronutrients, which are required in small amounts. Plant hormones such as auxins, cytokinins, gibberellins, abscisic acid, ethylene, and brassinosteroids coordinate growth, development, and responses to stimuli. Hormones regulate processes like cell
Cells require energy from external sources to perform tasks. Energy flows into ecosystems as sunlight and leaves as heat. Living cells obtain energy through photosynthesis or cellular respiration. Cellular respiration uses oxygen to completely oxidize glucose or other fuels and extract more energy in the form of ATP through oxidative phosphorylation. When oxygen is absent, cells use fermentation pathways to produce ATP without oxygen by converting pyruvate into other end products like ethanol or lactic acid. Both fermentation and cellular respiration involve glycolysis but differ in their final electron acceptors, with cellular respiration producing more ATP.
This document summarizes key concepts in plant genetics. It discusses:
1. Genes and chromosomes, and their roles in heredity and variation.
2. The cell cycle and its phases (interphase and mitosis/meiosis), which allow for cell division and reproduction.
3. Sources of variation like crossing over, independent assortment of chromosomes, and random fertilization during meiosis.
4. Mendel's experiments on true-breeding plants and his discovery of dominant and recessive alleles, and how they segregate and combine during reproduction according to the laws of inheritance.
5. Tools like Punnett squares that are used to predict outcomes of genetic crosses and inheritance of
This document provides information on DNA, genes, and heredity. It discusses that DNA is found in the nucleus and is made up of nucleotides. Genes, which are specific regions of DNA, code for enzymes and transfer hereditary traits. The central dogma is that DNA is transcribed into mRNA which is then translated into proteins. Modern techniques like genetic engineering can transfer genes between organisms to create transgenic plants with desired traits like pest resistance.
This document discusses various modes of transport in plants. It describes:
1) Passive transport processes like diffusion and osmosis that move substances down their concentration gradients without external energy input. Water potential and membrane transport proteins are also discussed.
2) Active transport mechanisms that require energy to move substances against gradients, such as sucrose-hydrogen cotransport.
3) Long distance transport within plants, including lateral transport in cell walls and plasmodesmata, as well as bulk flow transport in xylem and phloem between organs.
Programming Foundation Models with DSPy - Meetup SlidesZilliz
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Prompting language models is hard, while programming language models is easy. In this talk, I will discuss the state-of-the-art framework DSPy for programming foundation models with its powerful optimizers and runtime constraint system.
Have you ever been confused by the myriad of choices offered by AWS for hosting a website or an API?
Lambda, Elastic Beanstalk, Lightsail, Amplify, S3 (and more!) can each host websites + APIs. But which one should we choose?
Which one is cheapest? Which one is fastest? Which one will scale to meet our needs?
Join me in this session as we dive into each AWS hosting service to determine which one is best for your scenario and explain why!
Main news related to the CCS TSI 2023 (2023/1695)Jakub Marek
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An English 🇬🇧 translation of a presentation to the speech I gave about the main changes brought by CCS TSI 2023 at the biggest Czech conference on Communications and signalling systems on Railways, which was held in Clarion Hotel Olomouc from 7th to 9th November 2023 (konferenceszt.cz). Attended by around 500 participants and 200 on-line followers.
The original Czech 🇨🇿 version of the presentation can be found here: https://www.slideshare.net/slideshow/hlavni-novinky-souvisejici-s-ccs-tsi-2023-2023-1695/269688092 .
The videorecording (in Czech) from the presentation is available here: https://youtu.be/WzjJWm4IyPk?si=SImb06tuXGb30BEH .
5th LF Energy Power Grid Model Meet-up SlidesDanBrown980551
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5th Power Grid Model Meet-up
It is with great pleasure that we extend to you an invitation to the 5th Power Grid Model Meet-up, scheduled for 6th June 2024. This event will adopt a hybrid format, allowing participants to join us either through an online Mircosoft Teams session or in person at TU/e located at Den Dolech 2, Eindhoven, Netherlands. The meet-up will be hosted by Eindhoven University of Technology (TU/e), a research university specializing in engineering science & technology.
Power Grid Model
The global energy transition is placing new and unprecedented demands on Distribution System Operators (DSOs). Alongside upgrades to grid capacity, processes such as digitization, capacity optimization, and congestion management are becoming vital for delivering reliable services.
Power Grid Model is an open source project from Linux Foundation Energy and provides a calculation engine that is increasingly essential for DSOs. It offers a standards-based foundation enabling real-time power systems analysis, simulations of electrical power grids, and sophisticated what-if analysis. In addition, it enables in-depth studies and analysis of the electrical power grid’s behavior and performance. This comprehensive model incorporates essential factors such as power generation capacity, electrical losses, voltage levels, power flows, and system stability.
Power Grid Model is currently being applied in a wide variety of use cases, including grid planning, expansion, reliability, and congestion studies. It can also help in analyzing the impact of renewable energy integration, assessing the effects of disturbances or faults, and developing strategies for grid control and optimization.
What to expect
For the upcoming meetup we are organizing, we have an exciting lineup of activities planned:
-Insightful presentations covering two practical applications of the Power Grid Model.
-An update on the latest advancements in Power Grid -Model technology during the first and second quarters of 2024.
-An interactive brainstorming session to discuss and propose new feature requests.
-An opportunity to connect with fellow Power Grid Model enthusiasts and users.
AI 101: An Introduction to the Basics and Impact of Artificial IntelligenceIndexBug
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Imagine a world where machines not only perform tasks but also learn, adapt, and make decisions. This is the promise of Artificial Intelligence (AI), a technology that's not just enhancing our lives but revolutionizing entire industries.
GraphRAG for Life Science to increase LLM accuracyTomaz Bratanic
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GraphRAG for life science domain, where you retriever information from biomedical knowledge graphs using LLMs to increase the accuracy and performance of generated answers
HCL Notes and Domino License Cost Reduction in the World of DLAUpanagenda
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Webinar Recording: https://www.panagenda.com/webinars/hcl-notes-and-domino-license-cost-reduction-in-the-world-of-dlau/
The introduction of DLAU and the CCB & CCX licensing model caused quite a stir in the HCL community. As a Notes and Domino customer, you may have faced challenges with unexpected user counts and license costs. You probably have questions on how this new licensing approach works and how to benefit from it. Most importantly, you likely have budget constraints and want to save money where possible. Don’t worry, we can help with all of this!
We’ll show you how to fix common misconfigurations that cause higher-than-expected user counts, and how to identify accounts which you can deactivate to save money. There are also frequent patterns that can cause unnecessary cost, like using a person document instead of a mail-in for shared mailboxes. We’ll provide examples and solutions for those as well. And naturally we’ll explain the new licensing model.
Join HCL Ambassador Marc Thomas in this webinar with a special guest appearance from Franz Walder. It will give you the tools and know-how to stay on top of what is going on with Domino licensing. You will be able lower your cost through an optimized configuration and keep it low going forward.
These topics will be covered
- Reducing license cost by finding and fixing misconfigurations and superfluous accounts
- How do CCB and CCX licenses really work?
- Understanding the DLAU tool and how to best utilize it
- Tips for common problem areas, like team mailboxes, functional/test users, etc
- Practical examples and best practices to implement right away
Your One-Stop Shop for Python Success: Top 10 US Python Development Providersakankshawande
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Simplify your search for a reliable Python development partner! This list presents the top 10 trusted US providers offering comprehensive Python development services, ensuring your project's success from conception to completion.
OpenID AuthZEN Interop Read Out - AuthorizationDavid Brossard
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During Identiverse 2024 and EIC 2024, members of the OpenID AuthZEN WG got together and demoed their authorization endpoints conforming to the AuthZEN API
HCL Notes und Domino Lizenzkostenreduzierung in der Welt von DLAUpanagenda
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Webinar Recording: https://www.panagenda.com/webinars/hcl-notes-und-domino-lizenzkostenreduzierung-in-der-welt-von-dlau/
DLAU und die Lizenzen nach dem CCB- und CCX-Modell sind für viele in der HCL-Community seit letztem Jahr ein heißes Thema. Als Notes- oder Domino-Kunde haben Sie vielleicht mit unerwartet hohen Benutzerzahlen und Lizenzgebühren zu kämpfen. Sie fragen sich vielleicht, wie diese neue Art der Lizenzierung funktioniert und welchen Nutzen sie Ihnen bringt. Vor allem wollen Sie sicherlich Ihr Budget einhalten und Kosten sparen, wo immer möglich. Das verstehen wir und wir möchten Ihnen dabei helfen!
Wir erklären Ihnen, wie Sie häufige Konfigurationsprobleme lösen können, die dazu führen können, dass mehr Benutzer gezählt werden als nötig, und wie Sie überflüssige oder ungenutzte Konten identifizieren und entfernen können, um Geld zu sparen. Es gibt auch einige Ansätze, die zu unnötigen Ausgaben führen können, z. B. wenn ein Personendokument anstelle eines Mail-Ins für geteilte Mailboxen verwendet wird. Wir zeigen Ihnen solche Fälle und deren Lösungen. Und natürlich erklären wir Ihnen das neue Lizenzmodell.
Nehmen Sie an diesem Webinar teil, bei dem HCL-Ambassador Marc Thomas und Gastredner Franz Walder Ihnen diese neue Welt näherbringen. Es vermittelt Ihnen die Tools und das Know-how, um den Überblick zu bewahren. Sie werden in der Lage sein, Ihre Kosten durch eine optimierte Domino-Konfiguration zu reduzieren und auch in Zukunft gering zu halten.
Diese Themen werden behandelt
- Reduzierung der Lizenzkosten durch Auffinden und Beheben von Fehlkonfigurationen und überflüssigen Konten
- Wie funktionieren CCB- und CCX-Lizenzen wirklich?
- Verstehen des DLAU-Tools und wie man es am besten nutzt
- Tipps für häufige Problembereiche, wie z. B. Team-Postfächer, Funktions-/Testbenutzer usw.
- Praxisbeispiele und Best Practices zum sofortigen Umsetzen
Project Management Semester Long Project - Acuityjpupo2018
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Acuity is an innovative learning app designed to transform the way you engage with knowledge. Powered by AI technology, Acuity takes complex topics and distills them into concise, interactive summaries that are easy to read & understand. Whether you're exploring the depths of quantum mechanics or seeking insight into historical events, Acuity provides the key information you need without the burden of lengthy texts.
Salesforce Integration for Bonterra Impact Management (fka Social Solutions A...Jeffrey Haguewood
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Sidekick Solutions uses Bonterra Impact Management (fka Social Solutions Apricot) and automation solutions to integrate data for business workflows.
We believe integration and automation are essential to user experience and the promise of efficient work through technology. Automation is the critical ingredient to realizing that full vision. We develop integration products and services for Bonterra Case Management software to support the deployment of automations for a variety of use cases.
This video focuses on integration of Salesforce with Bonterra Impact Management.
Interested in deploying an integration with Salesforce for Bonterra Impact Management? Contact us at sales@sidekicksolutionsllc.com to discuss next steps.
Skybuffer SAM4U tool for SAP license adoptionTatiana Kojar
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Manage and optimize your license adoption and consumption with SAM4U, an SAP free customer software asset management tool.
SAM4U, an SAP complimentary software asset management tool for customers, delivers a detailed and well-structured overview of license inventory and usage with a user-friendly interface. We offer a hosted, cost-effective, and performance-optimized SAM4U setup in the Skybuffer Cloud environment. You retain ownership of the system and data, while we manage the ABAP 7.58 infrastructure, ensuring fixed Total Cost of Ownership (TCO) and exceptional services through the SAP Fiori interface.
How to Get CNIC Information System with Paksim Ga.pptxdanishmna97
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Pakdata Cf is a groundbreaking system designed to streamline and facilitate access to CNIC information. This innovative platform leverages advanced technology to provide users with efficient and secure access to their CNIC details.
Cosa hanno in comune un mattoncino Lego e la backdoor XZ?Speck&Tech
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ABSTRACT: A prima vista, un mattoncino Lego e la backdoor XZ potrebbero avere in comune il fatto di essere entrambi blocchi di costruzione, o dipendenze di progetti creativi e software. La realtà è che un mattoncino Lego e il caso della backdoor XZ hanno molto di più di tutto ciò in comune.
Partecipate alla presentazione per immergervi in una storia di interoperabilità , standard e formati aperti, per poi discutere del ruolo importante che i contributori hanno in una comunità open source sostenibile.
BIO: Sostenitrice del software libero e dei formati standard e aperti. È stata un membro attivo dei progetti Fedora e openSUSE e ha co-fondato l'Associazione LibreItalia dove è stata coinvolta in diversi eventi, migrazioni e formazione relativi a LibreOffice. In precedenza ha lavorato a migrazioni e corsi di formazione su LibreOffice per diverse amministrazioni pubbliche e privati. Da gennaio 2020 lavora in SUSE come Software Release Engineer per Uyuni e SUSE Manager e quando non segue la sua passione per i computer e per Geeko coltiva la sua curiosità per l'astronomia (da cui deriva il suo nickname deneb_alpha).
UiPath Test Automation using UiPath Test Suite series, part 6DianaGray10
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Welcome to UiPath Test Automation using UiPath Test Suite series part 6. In this session, we will cover Test Automation with generative AI and Open AI.
UiPath Test Automation with generative AI and Open AI webinar offers an in-depth exploration of leveraging cutting-edge technologies for test automation within the UiPath platform. Attendees will delve into the integration of generative AI, a test automation solution, with Open AI advanced natural language processing capabilities.
Throughout the session, participants will discover how this synergy empowers testers to automate repetitive tasks, enhance testing accuracy, and expedite the software testing life cycle. Topics covered include the seamless integration process, practical use cases, and the benefits of harnessing AI-driven automation for UiPath testing initiatives. By attending this webinar, testers, and automation professionals can gain valuable insights into harnessing the power of AI to optimize their test automation workflows within the UiPath ecosystem, ultimately driving efficiency and quality in software development processes.
What will you get from this session?
1. Insights into integrating generative AI.
2. Understanding how this integration enhances test automation within the UiPath platform
3. Practical demonstrations
4. Exploration of real-world use cases illustrating the benefits of AI-driven test automation for UiPath
Topics covered:
What is generative AI
Test Automation with generative AI and Open AI.
UiPath integration with generative AI
Speaker:
Deepak Rai, Automation Practice Lead, Boundaryless Group and UiPath MVP