This document discusses key concepts in ecosystems including ecological succession, the carbon dioxide and nitrogen cycles, ecological pyramids, food webs, and the symbiotic relationships of commensalism, parasitism, and mutualism.
The document provides information about biogeochemical cycles. It discusses the water, carbon, oxygen, and nitrogen cycles. For each cycle it describes the reservoirs, how the element moves into living things, how it is returned to the Earth, and human impacts. The document emphasizes that these are continuous cycles that have always recycled these essential elements between living things and the non-living environment.
Biogeochemical cycles describe the movement of elements and molecules through biotic and abiotic components of ecosystems. Major cycles include carbon, nitrogen, oxygen, phosphorus, and sulfur, which circulate crucial nutrients through the biosphere, hydrosphere, atmosphere, and lithosphere. These recycling processes are essential to sustaining life as they maintain the chemical conditions necessary for organisms to survive.
Evald Maceno is a graduate student at UPR writing an outline for a class on coastal environments. The document outlines carbon as an element and its physical and chemical properties. It describes carbon as part of a global cycle, moving between the atmosphere, biosphere, lithosphere, and hydrosphere. This carbon cycle is impacted by human activities like burning fossil fuels and deforestation, which increase CO2 levels and acidify the oceans. Rising ocean temperatures and acidification threaten marine life and food systems.
The document summarizes the nitrogen cycle. It describes the key steps:
1) Nitrogen fixation converts nitrogen gas to ammonia through diazotroph bacteria.
2) Nitrification converts ammonia to nitrites and nitrates through nitrifying bacteria.
3) Plants and animals assimilate nitrates and ammonia for growth.
4) Decomposition returns nitrogen to the soil as ammonium through ammonification.
5) Denitrification releases nitrogen back to the atmosphere through soil bacteria.
Human activities like deforestation and fertilizer use can disturb nitrogen cycles and negatively impact the environment through acid rain, global warming, and pollution.
The nitrogen cycle is a natural process in which atmospheric nitrogen enters the soil and becomes part of living organisms. It is essential to living things and plays an important role in ecosystems. The steps of the nitrogen cycle are nitrogen fixation, nitrogen assimilation, ammonification, nitrification, and denitrification. Human activities like cultivation, harvesting, and fossil fuel use can disrupt the nitrogen cycle and cause over-supply of nitrogen in the environment, leading to issues like soil acidification and increased greenhouse gases.
The carbon cycle describes how carbon is transferred between living organisms and the environment in different ways. Carbon is contained in all living things and moves through cellular respiration, photosynthesis, combustion, decomposition, and sedimentation. It can be absorbed by plants through photosynthesis, released through cellular respiration and combustion, and eventually deposited as sediment over long periods of time.
The document discusses the carbon cycle, which involves the movement of carbon between different reservoirs on Earth, including the atmosphere, oceans, biosphere, and lithosphere. Carbon cycles through these reservoirs through various processes on timescales ranging from years to millions of years. Key aspects of the carbon cycle include photosynthesis, respiration, decomposition, weathering of rocks, deep ocean storage, and the formation and combustion of fossil fuels.
The document discusses several biogeochemical cycles including the water, carbon, and nitrogen cycles. The water cycle involves evaporation, condensation, precipitation, and transpiration moving water between the atmosphere and Earth's surface. The carbon cycle moves carbon between the atmosphere, organisms, oceans, fossil fuels, and soil through photosynthesis, respiration, and decomposition. Nitrogen is converted between gas and organic forms through nitrogen fixation by bacteria, decomposition, and nitrification and denitrification by other bacteria.
The document provides information about biogeochemical cycles. It discusses the water, carbon, oxygen, and nitrogen cycles. For each cycle it describes the reservoirs, how the element moves into living things, how it is returned to the Earth, and human impacts. The document emphasizes that these are continuous cycles that have always recycled these essential elements between living things and the non-living environment.
Biogeochemical cycles describe the movement of elements and molecules through biotic and abiotic components of ecosystems. Major cycles include carbon, nitrogen, oxygen, phosphorus, and sulfur, which circulate crucial nutrients through the biosphere, hydrosphere, atmosphere, and lithosphere. These recycling processes are essential to sustaining life as they maintain the chemical conditions necessary for organisms to survive.
Evald Maceno is a graduate student at UPR writing an outline for a class on coastal environments. The document outlines carbon as an element and its physical and chemical properties. It describes carbon as part of a global cycle, moving between the atmosphere, biosphere, lithosphere, and hydrosphere. This carbon cycle is impacted by human activities like burning fossil fuels and deforestation, which increase CO2 levels and acidify the oceans. Rising ocean temperatures and acidification threaten marine life and food systems.
The document summarizes the nitrogen cycle. It describes the key steps:
1) Nitrogen fixation converts nitrogen gas to ammonia through diazotroph bacteria.
2) Nitrification converts ammonia to nitrites and nitrates through nitrifying bacteria.
3) Plants and animals assimilate nitrates and ammonia for growth.
4) Decomposition returns nitrogen to the soil as ammonium through ammonification.
5) Denitrification releases nitrogen back to the atmosphere through soil bacteria.
Human activities like deforestation and fertilizer use can disturb nitrogen cycles and negatively impact the environment through acid rain, global warming, and pollution.
The nitrogen cycle is a natural process in which atmospheric nitrogen enters the soil and becomes part of living organisms. It is essential to living things and plays an important role in ecosystems. The steps of the nitrogen cycle are nitrogen fixation, nitrogen assimilation, ammonification, nitrification, and denitrification. Human activities like cultivation, harvesting, and fossil fuel use can disrupt the nitrogen cycle and cause over-supply of nitrogen in the environment, leading to issues like soil acidification and increased greenhouse gases.
The carbon cycle describes how carbon is transferred between living organisms and the environment in different ways. Carbon is contained in all living things and moves through cellular respiration, photosynthesis, combustion, decomposition, and sedimentation. It can be absorbed by plants through photosynthesis, released through cellular respiration and combustion, and eventually deposited as sediment over long periods of time.
The document discusses the carbon cycle, which involves the movement of carbon between different reservoirs on Earth, including the atmosphere, oceans, biosphere, and lithosphere. Carbon cycles through these reservoirs through various processes on timescales ranging from years to millions of years. Key aspects of the carbon cycle include photosynthesis, respiration, decomposition, weathering of rocks, deep ocean storage, and the formation and combustion of fossil fuels.
The document discusses several biogeochemical cycles including the water, carbon, and nitrogen cycles. The water cycle involves evaporation, condensation, precipitation, and transpiration moving water between the atmosphere and Earth's surface. The carbon cycle moves carbon between the atmosphere, organisms, oceans, fossil fuels, and soil through photosynthesis, respiration, and decomposition. Nitrogen is converted between gas and organic forms through nitrogen fixation by bacteria, decomposition, and nitrification and denitrification by other bacteria.
The nitrogen cycle describes how nitrogen is converted between its gas form in the atmosphere and forms that can be used by plants and animals. Nitrogen is converted to nitrates that plants can use through lightning or nitrogen-fixing bacteria. Phosphorus cycles through rocks, soil, and organisms and is essential for life. When organisms die, their phosphorus is returned to the soil through bacteria.
The document discusses the oxygen cycle on Earth, including the major sources and sinks of oxygen. It notes that photosynthesis by plants and phytoplankton is the primary source of oxygen, producing about 30,000 teragrams of oxygen per year. Respiration by animals and decay of organic matter act as sinks and consume a similar amount, keeping atmospheric oxygen concentrations relatively stable over time.
Science 24-7 is another affiliate of sciencetutors and webscience. Please see more resources at www.sciencetutors.zoomshare.com
Email for all science24-7 correspondence is: sciencetutorshelpdesk@gmail.com
The document discusses the carbon cycle and how carbon moves between organic and inorganic forms through photosynthesis and cellular respiration. It describes how producers convert carbon dioxide into organic compounds through photosynthesis, and how consumers and producers return carbon dioxide to the atmosphere through cellular respiration. It also discusses how carbon is absorbed by oceans and sediments, and incorporated into shells, coral, and limestone over long periods of time. The document then explains how humans disrupt the natural carbon cycle by burning fossil fuels, releasing carbon that has been fixed for thousands of years back into the atmosphere as carbon dioxide. This increased carbon dioxide is contributing to rising global temperatures and global warming.
The document summarizes several biogeochemical cycles, including the water, carbon, nitrogen, phosphorus, and calcium cycles. It describes the key components and processes involved in each cycle, such as evaporation and precipitation in the water cycle, photosynthesis and respiration in the carbon cycle, nitrogen fixation and nitrification in the nitrogen cycle, and the role of these elements as important nutrients. It also notes how human activities like burning fossil fuels, agriculture, and industry can impact these natural cycles.
The document summarizes several biogeochemical cycles including nitrogen and phosphorus cycles. It describes how nitrogen and phosphorus cycle through ecosystems via biological and geological processes. For the nitrogen cycle, it outlines the five key steps of nitrogen fixation, assimilation, mineralization, nitrification, and denitrification. It provides details on the microorganisms involved in each step and factors that control the processes. The same level of detail is provided for the phosphorus cycle which involves mineralization, assimilation, precipitation of phosphorus compounds, and microbial solubilization of phosphorus.
The document summarizes two important biogeochemical cycles - the nitrogen cycle and the carbon dioxide-oxygen cycle.
The nitrogen cycle describes how nitrogen exists in different forms and moves between the atmosphere, living things, and the lithosphere through natural processes like nitrogen fixation, assimilation, decomposition, nitrification, and denitrification. Human activities like using nitrogen fertilizers and burning fossil fuels can impact the nitrogen cycle.
The carbon dioxide-oxygen cycle explains how carbon dioxide and oxygen are exchanged between living things and the atmosphere through photosynthesis, respiration, and combustion. Photosynthesis produces oxygen and food, respiration uses oxygen and food to produce energy, and combustion releases carbon dioxide through burning fuels. Human activities such as def
The document discusses three major biogeochemical cycles - the water cycle, carbon cycle, and nitrogen cycle. It provides details on how water, carbon, and nitrogen move through biotic and abiotic factors in the environment. Water cycles through precipitation, evaporation, transpiration, runoff and groundwater. Carbon cycles through photosynthesis, respiration, decomposition and combustion. Nitrogen cycles through nitrogen fixation by soil bacteria and lightning, and denitrification by other soil bacteria.
The carbon cycle describes the movement of carbon between the biosphere, geosphere, hydrosphere and atmosphere. Carbon is incorporated into living things through photosynthesis and returns to the atmosphere and water through respiration, combustion and decomposition. It can also be buried deep underground over millions of years and later released through events like volcanic eruptions. The cycling of carbon is crucial for supporting life and regulating Earth's climate.
Bio 107 General Ecology
Objectives:
Identify and describe
the flow of nutrients in
each biogeochemical
cycle.
Explain the impact
that humans have on
the biogeochemical
cycles.
The document summarizes several biogeochemical cycles, including the water, oxygen, carbon, phosphorus, nitrogen, and sulfur cycles. It describes the key processes in each cycle, such as evaporation and precipitation in the water cycle, photosynthesis and cellular respiration in the oxygen cycle, and fixation, nitrification, and denitrification in the nitrogen cycle. It also discusses how human activities like burning fossil fuels, clearing vegetation, and use of fertilizers impact these natural cycles.
This document discusses carbon dioxide in the ocean. It explains that CO2 enters the oceans through air-sea exchange and is used by oceans as a carbon sink. During El Nino events, less CO2 is released from the oceans due to lack of upwelling and increased wildfires. The thermohaline circulation transports heat and affects CO2 levels in the oceans, but rising CO2 levels could disrupt this circulation pattern. Increased ocean CO2 is causing ocean acidification which damages coral reefs and marine life.
Biogeochemical Cycles and Human ActivitiesAmos Watentena
A biogeochemical cycle is one of several natural cycles, in which conserved matter moves through the biotic and abiotic parts of an ecosystem. In geography and Earth science, a biogeochemical cycle or substance turnover or cycling of substances is a pathway by which a chemical substance moves through biotic (biosphere) and abiotic (lithosphere, atmosphere, and hydrosphere) compartments of Earth. The following presentation discusses the role of humans in the biogeochemical cycles.
The carbon cycle is a complex series of processes through which carbon atoms are recycled and reused. Plants absorb carbon dioxide from the atmosphere through photosynthesis and animals release carbon dioxide through respiration, allowing carbon to be reused. The carbon cycle is essential for producing food and renewable resources through photosynthesis and decomposition, and serves as the earth's waste disposal system through decomposition. It also affects the climate as carbon dioxide in the atmosphere causes warming.
The document discusses three nutrient cycles - carbon, water, and nitrogen. The carbon cycle involves the removal of CO2 from the atmosphere through photosynthesis by plants and its return through respiration by animals and decomposers. Fossil fuels also add CO2 when burned. The water cycle involves the constant circulation of water between the atmosphere, land, and oceans through evaporation and precipitation. The nitrogen cycle converts nitrogen in the air into nitrogen in the soil through fixation by bacteria and lightning, and back through the decay of animal and plant matter.
More advanced treatise of the carbon and nitrogen cycles. Could be useful for teachers who have limited science background or for students in upper middle or high school.
The document summarizes several natural cycles:
1) The carbon cycle involves carbon sinks like plants, forests and soil that absorb carbon, and carbon sources like combustion, respiration and decomposition that release carbon.
2) Nitrogen fixation converts inert nitrogen gas into bio-usable forms through atmospheric fixation by lightning or biological fixation by microbes and plants. Nitrification converts ammonia into nitrites and nitrates which plants can use but are soluble and can leach from soil.
3) The hydrological cycle describes the continuous movement of water above, on and below the Earth's surface, with the same amount of water circulating but individual molecules coming and going quickly.
Decay and the Carbon Cycle discusses how decay returns materials to the environment through a natural cycle. It focuses on three key points: how plants and animals decay and return nutrients to soil, the type of organism (fungi) that causes leaves to rot, and how higher temperatures in summer cause leaves to decay faster. The document explores the factors like oxygen, water, and temperature that affect the rate of decay and how decay is useful for recycling nutrients and forming fossil fuels over time.
The nitrogen cycle describes how nitrogen is converted between its gas form in the atmosphere and forms that can be used by plants and animals. Nitrogen is converted to nitrates that plants can use through lightning or nitrogen-fixing bacteria. Phosphorus cycles through rocks, soil, and organisms and is essential for life. When organisms die, their phosphorus is returned to the soil through bacteria.
The document discusses the oxygen cycle on Earth, including the major sources and sinks of oxygen. It notes that photosynthesis by plants and phytoplankton is the primary source of oxygen, producing about 30,000 teragrams of oxygen per year. Respiration by animals and decay of organic matter act as sinks and consume a similar amount, keeping atmospheric oxygen concentrations relatively stable over time.
Science 24-7 is another affiliate of sciencetutors and webscience. Please see more resources at www.sciencetutors.zoomshare.com
Email for all science24-7 correspondence is: sciencetutorshelpdesk@gmail.com
The document discusses the carbon cycle and how carbon moves between organic and inorganic forms through photosynthesis and cellular respiration. It describes how producers convert carbon dioxide into organic compounds through photosynthesis, and how consumers and producers return carbon dioxide to the atmosphere through cellular respiration. It also discusses how carbon is absorbed by oceans and sediments, and incorporated into shells, coral, and limestone over long periods of time. The document then explains how humans disrupt the natural carbon cycle by burning fossil fuels, releasing carbon that has been fixed for thousands of years back into the atmosphere as carbon dioxide. This increased carbon dioxide is contributing to rising global temperatures and global warming.
The document summarizes several biogeochemical cycles, including the water, carbon, nitrogen, phosphorus, and calcium cycles. It describes the key components and processes involved in each cycle, such as evaporation and precipitation in the water cycle, photosynthesis and respiration in the carbon cycle, nitrogen fixation and nitrification in the nitrogen cycle, and the role of these elements as important nutrients. It also notes how human activities like burning fossil fuels, agriculture, and industry can impact these natural cycles.
The document summarizes several biogeochemical cycles including nitrogen and phosphorus cycles. It describes how nitrogen and phosphorus cycle through ecosystems via biological and geological processes. For the nitrogen cycle, it outlines the five key steps of nitrogen fixation, assimilation, mineralization, nitrification, and denitrification. It provides details on the microorganisms involved in each step and factors that control the processes. The same level of detail is provided for the phosphorus cycle which involves mineralization, assimilation, precipitation of phosphorus compounds, and microbial solubilization of phosphorus.
The document summarizes two important biogeochemical cycles - the nitrogen cycle and the carbon dioxide-oxygen cycle.
The nitrogen cycle describes how nitrogen exists in different forms and moves between the atmosphere, living things, and the lithosphere through natural processes like nitrogen fixation, assimilation, decomposition, nitrification, and denitrification. Human activities like using nitrogen fertilizers and burning fossil fuels can impact the nitrogen cycle.
The carbon dioxide-oxygen cycle explains how carbon dioxide and oxygen are exchanged between living things and the atmosphere through photosynthesis, respiration, and combustion. Photosynthesis produces oxygen and food, respiration uses oxygen and food to produce energy, and combustion releases carbon dioxide through burning fuels. Human activities such as def
The document discusses three major biogeochemical cycles - the water cycle, carbon cycle, and nitrogen cycle. It provides details on how water, carbon, and nitrogen move through biotic and abiotic factors in the environment. Water cycles through precipitation, evaporation, transpiration, runoff and groundwater. Carbon cycles through photosynthesis, respiration, decomposition and combustion. Nitrogen cycles through nitrogen fixation by soil bacteria and lightning, and denitrification by other soil bacteria.
The carbon cycle describes the movement of carbon between the biosphere, geosphere, hydrosphere and atmosphere. Carbon is incorporated into living things through photosynthesis and returns to the atmosphere and water through respiration, combustion and decomposition. It can also be buried deep underground over millions of years and later released through events like volcanic eruptions. The cycling of carbon is crucial for supporting life and regulating Earth's climate.
Bio 107 General Ecology
Objectives:
Identify and describe
the flow of nutrients in
each biogeochemical
cycle.
Explain the impact
that humans have on
the biogeochemical
cycles.
The document summarizes several biogeochemical cycles, including the water, oxygen, carbon, phosphorus, nitrogen, and sulfur cycles. It describes the key processes in each cycle, such as evaporation and precipitation in the water cycle, photosynthesis and cellular respiration in the oxygen cycle, and fixation, nitrification, and denitrification in the nitrogen cycle. It also discusses how human activities like burning fossil fuels, clearing vegetation, and use of fertilizers impact these natural cycles.
This document discusses carbon dioxide in the ocean. It explains that CO2 enters the oceans through air-sea exchange and is used by oceans as a carbon sink. During El Nino events, less CO2 is released from the oceans due to lack of upwelling and increased wildfires. The thermohaline circulation transports heat and affects CO2 levels in the oceans, but rising CO2 levels could disrupt this circulation pattern. Increased ocean CO2 is causing ocean acidification which damages coral reefs and marine life.
Biogeochemical Cycles and Human ActivitiesAmos Watentena
A biogeochemical cycle is one of several natural cycles, in which conserved matter moves through the biotic and abiotic parts of an ecosystem. In geography and Earth science, a biogeochemical cycle or substance turnover or cycling of substances is a pathway by which a chemical substance moves through biotic (biosphere) and abiotic (lithosphere, atmosphere, and hydrosphere) compartments of Earth. The following presentation discusses the role of humans in the biogeochemical cycles.
The carbon cycle is a complex series of processes through which carbon atoms are recycled and reused. Plants absorb carbon dioxide from the atmosphere through photosynthesis and animals release carbon dioxide through respiration, allowing carbon to be reused. The carbon cycle is essential for producing food and renewable resources through photosynthesis and decomposition, and serves as the earth's waste disposal system through decomposition. It also affects the climate as carbon dioxide in the atmosphere causes warming.
The document discusses three nutrient cycles - carbon, water, and nitrogen. The carbon cycle involves the removal of CO2 from the atmosphere through photosynthesis by plants and its return through respiration by animals and decomposers. Fossil fuels also add CO2 when burned. The water cycle involves the constant circulation of water between the atmosphere, land, and oceans through evaporation and precipitation. The nitrogen cycle converts nitrogen in the air into nitrogen in the soil through fixation by bacteria and lightning, and back through the decay of animal and plant matter.
More advanced treatise of the carbon and nitrogen cycles. Could be useful for teachers who have limited science background or for students in upper middle or high school.
The document summarizes several natural cycles:
1) The carbon cycle involves carbon sinks like plants, forests and soil that absorb carbon, and carbon sources like combustion, respiration and decomposition that release carbon.
2) Nitrogen fixation converts inert nitrogen gas into bio-usable forms through atmospheric fixation by lightning or biological fixation by microbes and plants. Nitrification converts ammonia into nitrites and nitrates which plants can use but are soluble and can leach from soil.
3) The hydrological cycle describes the continuous movement of water above, on and below the Earth's surface, with the same amount of water circulating but individual molecules coming and going quickly.
Decay and the Carbon Cycle discusses how decay returns materials to the environment through a natural cycle. It focuses on three key points: how plants and animals decay and return nutrients to soil, the type of organism (fungi) that causes leaves to rot, and how higher temperatures in summer cause leaves to decay faster. The document explores the factors like oxygen, water, and temperature that affect the rate of decay and how decay is useful for recycling nutrients and forming fossil fuels over time.
HCL Notes und Domino Lizenzkostenreduzierung in der Welt von DLAUpanagenda
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
Maruthi Prithivirajan, Head of ASEAN & IN Solution Architecture, Neo4j
Get an inside look at the latest Neo4j innovations that enable relationship-driven intelligence at scale. Learn more about the newest cloud integrations and product enhancements that make Neo4j an essential choice for developers building apps with interconnected data and generative AI.
GraphSummit Singapore | The Art of the Possible with Graph - Q2 2024Neo4j
Neha Bajwa, Vice President of Product Marketing, Neo4j
Join us as we explore breakthrough innovations enabled by interconnected data and AI. Discover firsthand how organizations use relationships in data to uncover contextual insights and solve our most pressing challenges – from optimizing supply chains, detecting fraud, and improving customer experiences to accelerating drug discoveries.
Building Production Ready Search Pipelines with Spark and MilvusZilliz
Spark is the widely used ETL tool for processing, indexing and ingesting data to serving stack for search. Milvus is the production-ready open-source vector database. In this talk we will show how to use Spark to process unstructured data to extract vector representations, and push the vectors to Milvus vector database for search serving.
“An Outlook of the Ongoing and Future Relationship between Blockchain Technologies and Process-aware Information Systems.” Invited talk at the joint workshop on Blockchain for Information Systems (BC4IS) and Blockchain for Trusted Data Sharing (B4TDS), co-located with with the 36th International Conference on Advanced Information Systems Engineering (CAiSE), 3 June 2024, Limassol, Cyprus.
UiPath Test Automation using UiPath Test Suite series, part 6DianaGray10
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
UiPath Test Automation using UiPath Test Suite series, part 5DianaGray10
Welcome to UiPath Test Automation using UiPath Test Suite series part 5. In this session, we will cover CI/CD with devops.
Topics covered:
CI/CD with in UiPath
End-to-end overview of CI/CD pipeline with Azure devops
Speaker:
Lyndsey Byblow, Test Suite Sales Engineer @ UiPath, Inc.
Goodbye Windows 11: Make Way for Nitrux Linux 3.5.0!SOFTTECHHUB
As the digital landscape continually evolves, operating systems play a critical role in shaping user experiences and productivity. The launch of Nitrux Linux 3.5.0 marks a significant milestone, offering a robust alternative to traditional systems such as Windows 11. This article delves into the essence of Nitrux Linux 3.5.0, exploring its unique features, advantages, and how it stands as a compelling choice for both casual users and tech enthusiasts.
Cosa hanno in comune un mattoncino Lego e la backdoor XZ?Speck&Tech
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).
Removing Uninteresting Bytes in Software FuzzingAftab Hussain
Imagine a world where software fuzzing, the process of mutating bytes in test seeds to uncover hidden and erroneous program behaviors, becomes faster and more effective. A lot depends on the initial seeds, which can significantly dictate the trajectory of a fuzzing campaign, particularly in terms of how long it takes to uncover interesting behaviour in your code. We introduce DIAR, a technique designed to speedup fuzzing campaigns by pinpointing and eliminating those uninteresting bytes in the seeds. Picture this: instead of wasting valuable resources on meaningless mutations in large, bloated seeds, DIAR removes the unnecessary bytes, streamlining the entire process.
In this work, we equipped AFL, a popular fuzzer, with DIAR and examined two critical Linux libraries -- Libxml's xmllint, a tool for parsing xml documents, and Binutil's readelf, an essential debugging and security analysis command-line tool used to display detailed information about ELF (Executable and Linkable Format). Our preliminary results show that AFL+DIAR does not only discover new paths more quickly but also achieves higher coverage overall. This work thus showcases how starting with lean and optimized seeds can lead to faster, more comprehensive fuzzing campaigns -- and DIAR helps you find such seeds.
- These are slides of the talk given at IEEE International Conference on Software Testing Verification and Validation Workshop, ICSTW 2022.
How to Get CNIC Information System with Paksim Ga.pptxdanishmna97
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.
In the rapidly evolving landscape of technologies, XML continues to play a vital role in structuring, storing, and transporting data across diverse systems. The recent advancements in artificial intelligence (AI) present new methodologies for enhancing XML development workflows, introducing efficiency, automation, and intelligent capabilities. This presentation will outline the scope and perspective of utilizing AI in XML development. The potential benefits and the possible pitfalls will be highlighted, providing a balanced view of the subject.
We will explore the capabilities of AI in understanding XML markup languages and autonomously creating structured XML content. Additionally, we will examine the capacity of AI to enrich plain text with appropriate XML markup. Practical examples and methodological guidelines will be provided to elucidate how AI can be effectively prompted to interpret and generate accurate XML markup.
Further emphasis will be placed on the role of AI in developing XSLT, or schemas such as XSD and Schematron. We will address the techniques and strategies adopted to create prompts for generating code, explaining code, or refactoring the code, and the results achieved.
The discussion will extend to how AI can be used to transform XML content. In particular, the focus will be on the use of AI XPath extension functions in XSLT, Schematron, Schematron Quick Fixes, or for XML content refactoring.
The presentation aims to deliver a comprehensive overview of AI usage in XML development, providing attendees with the necessary knowledge to make informed decisions. Whether you’re at the early stages of adopting AI or considering integrating it in advanced XML development, this presentation will cover all levels of expertise.
By highlighting the potential advantages and challenges of integrating AI with XML development tools and languages, the presentation seeks to inspire thoughtful conversation around the future of XML development. We’ll not only delve into the technical aspects of AI-powered XML development but also discuss practical implications and possible future directions.
Threats to mobile devices are more prevalent and increasing in scope and complexity. Users of mobile devices desire to take full advantage of the features
available on those devices, but many of the features provide convenience and capability but sacrifice security. This best practices guide outlines steps the users can take to better protect personal devices and information.