Electricity can shock you and is needed to power light bulbs through a series circuit. Lightning is a form of electricity that can come from rain clouds.
Lightning is a fast and bright electrical phenomenon that can start fires by striking objects and knocking down power poles, while electricity also flows through power lines and creates light by carrying electrical charges through the filaments of light bulbs.
This document outlines the materials and steps needed to complete an electronics project using diodes, resistors, wire in different gauges, magnets, clips, and a transistor. The wire is wound together into a spool with over 900 turns and then magnets are placed on a wheel before the wiring is connected to clips and a transistor to finish the project.
Arilyn and Circuit face off, using their superpowers against each other. Arilyn freezes Circuit's sonar gun and the surrounding air, requiring 995.626822 Watts of power. She then blows up the gun by vaporizing it, requiring 4689.5 Watts. Circuit stuns Arilyn with 300,000 volts. When Arilyn freezes Circuit, requiring 455697.75 Watts of power, and she causes his computer to catch fire by vaporizing the fans, requiring 4811.31 Watts of power over 0.4 seconds.
The fuse protects electric circuits from excessive current by containing a wire that melts when overheated. There are two main types: replaceable wire fuses and cartridge fuses. The fuse rating indicates the maximum current it can withstand without melting. Fuses should be rated slightly higher than the appliance's normal current to prevent tripping during regular use. Earth wires connect appliances to ground and provide a path for current in case of a loose live wire, preventing electric shocks.
This document discusses the history and techniques of wireless electricity transmission. It begins with defining witricity as the transmission of energy through the air without wires. It then reviews the early attempts by Nikola Tesla in the late 1800s and discusses the main techniques of inductive coupling, resonant inductive coupling, and microwave transmission. Applications including charging electric vehicles and devices wirelessly are demonstrated. While wireless power has advantages like more efficient and reliable power access, challenges remain in frequency tuning for short-range methods and potential health impacts of long-range microwave transmission. The conclusion is that a completely wireless world for energy transmission will likely be realized in the near future.
Witricity is a technology that wirelessly transfers electrical energy between two objects using magnetic resonance. It was first proposed by Nikola Tesla in 1899, but recent research and development has improved efficiency. Witricity works by generating oscillating magnetic fields between two coils - one powered and one receiving power. While it has advantages like eliminating wires and cables, challenges remain around standardization, costs, and potential for energy theft. Possible applications include charging consumer electronics, electric vehicles, and industrial equipment without plugs.
Electricity through wireless transmission witricityApoorva B
1) Wireless power transmission through resonance coupling was proposed by Nikola Tesla in 1899 and experiments were conducted at MIT to transmit power without wires over short distances.
2) Witricity uses resonant inductive coupling to efficiently transfer power between two electromagnetic resonators over mid-range distances without power loss.
3) Applications of wireless power include powering consumer electronics, electric vehicles, and industrial/transportation systems without wires, helping reduce e-waste and installation costs.
The document discusses conductors, insulators, and electric circuits. It defines an electric current as the flow of electrons and explains that current is measured in amps and voltage is measured in volts. It describes series circuits where current flows through components one at a time and parallel circuits where current flows through each component separately. A short circuit occurs when a wire allows current to flow past a component, which can be dangerous due to high current.
Lightning is a fast and bright electrical phenomenon that can start fires by striking objects and knocking down power poles, while electricity also flows through power lines and creates light by carrying electrical charges through the filaments of light bulbs.
This document outlines the materials and steps needed to complete an electronics project using diodes, resistors, wire in different gauges, magnets, clips, and a transistor. The wire is wound together into a spool with over 900 turns and then magnets are placed on a wheel before the wiring is connected to clips and a transistor to finish the project.
Arilyn and Circuit face off, using their superpowers against each other. Arilyn freezes Circuit's sonar gun and the surrounding air, requiring 995.626822 Watts of power. She then blows up the gun by vaporizing it, requiring 4689.5 Watts. Circuit stuns Arilyn with 300,000 volts. When Arilyn freezes Circuit, requiring 455697.75 Watts of power, and she causes his computer to catch fire by vaporizing the fans, requiring 4811.31 Watts of power over 0.4 seconds.
The fuse protects electric circuits from excessive current by containing a wire that melts when overheated. There are two main types: replaceable wire fuses and cartridge fuses. The fuse rating indicates the maximum current it can withstand without melting. Fuses should be rated slightly higher than the appliance's normal current to prevent tripping during regular use. Earth wires connect appliances to ground and provide a path for current in case of a loose live wire, preventing electric shocks.
This document discusses the history and techniques of wireless electricity transmission. It begins with defining witricity as the transmission of energy through the air without wires. It then reviews the early attempts by Nikola Tesla in the late 1800s and discusses the main techniques of inductive coupling, resonant inductive coupling, and microwave transmission. Applications including charging electric vehicles and devices wirelessly are demonstrated. While wireless power has advantages like more efficient and reliable power access, challenges remain in frequency tuning for short-range methods and potential health impacts of long-range microwave transmission. The conclusion is that a completely wireless world for energy transmission will likely be realized in the near future.
Witricity is a technology that wirelessly transfers electrical energy between two objects using magnetic resonance. It was first proposed by Nikola Tesla in 1899, but recent research and development has improved efficiency. Witricity works by generating oscillating magnetic fields between two coils - one powered and one receiving power. While it has advantages like eliminating wires and cables, challenges remain around standardization, costs, and potential for energy theft. Possible applications include charging consumer electronics, electric vehicles, and industrial equipment without plugs.
Electricity through wireless transmission witricityApoorva B
1) Wireless power transmission through resonance coupling was proposed by Nikola Tesla in 1899 and experiments were conducted at MIT to transmit power without wires over short distances.
2) Witricity uses resonant inductive coupling to efficiently transfer power between two electromagnetic resonators over mid-range distances without power loss.
3) Applications of wireless power include powering consumer electronics, electric vehicles, and industrial/transportation systems without wires, helping reduce e-waste and installation costs.
The document discusses conductors, insulators, and electric circuits. It defines an electric current as the flow of electrons and explains that current is measured in amps and voltage is measured in volts. It describes series circuits where current flows through components one at a time and parallel circuits where current flows through each component separately. A short circuit occurs when a wire allows current to flow past a component, which can be dangerous due to high current.
The document discusses basic electrical wiring and safety. It notes that approximately 290 people die from accidental electrocutions each year in the US, while another 800 die in fires caused by faulty electrical systems. Thousands more are injured. The document then defines electricity as the flow of electrons in a conductor, and notes there are two types of current: direct and alternating. It explains electrical service into homes and businesses, service panels, circuit breakers, cable types, common symbols used in diagrams, and basic receptacle wiring.
The document discusses the working of a light dependent resistor (LDR) and designing a circuit to demonstrate its varying resistance. It begins by introducing LDRs and explaining that their resistivity decreases when light is absorbed. It then describes building a circuit using an LDR, resistor, battery, LED, and breadboard. The circuit works by changing the LDR's resistance based on light intensity, which controls current flow through the LED. Finally, applications of LDRs include light sensors for street lamps, alarms, and automatic controls that require detecting light levels.
This document discusses nuclear fusion as a source of energy. It provides an overview of fusion, including what it is, the conditions needed to achieve it, and its safety advantages over other energy sources. ITER is introduced as a large-scale international project working to develop fusion as an energy source. Key points covered include how deuterium and tritium are used as fuel, the extremely high temperatures required to fuse atomic nuclei, and how magnetic confinement is used to control the plasma within the reactor.
Wireless power Transmission is the process of transferring the electrical energy from one place to another place without use of any wire or cord or cable. It requires resonating coupling between two points called source and destination.
F. Magnetron Deconstruction and Antenna AdaptationKurt Zeller
1) The document discusses deconstructing magnetrons from microwave ovens to use their resonant cavities and tap wires as antennas for experimentation.
2) Connecting the tap wire to an SMA connector was difficult due to material incompatibilities between the copper cavity and stainless steel panel mount.
3) Simulating the magnetron output in EM Pro software proved too complex, so plane wave simulations were used instead. Reducing the magnetron's 900-1000W output power was also explored through circuit designs.
This document outlines the tentative agendas for three introductory training sessions on electronics and electromagnetics simulation using ANSYS software: SIwave, HFSS, and Maxwell. Each session includes morning and afternoon blocks with lectures and workshops covering various simulation topics like import processes, s-parameters, impedance profiles, signal integrity, electromagnetic interference, eigenmodes, meshing, optimization, transient analysis, magnetostatics, electrostatics, eddy currents, magnetic transients, parametric analysis, and multiphysics coupling. Coffee breaks separate the morning and afternoon portions.
Iwt unit 5 laser beam welding sushant bhattSRMUBarabanki
Laser beam welding uses a concentrated coherent light beam to produce coalescence of materials. It works by exciting atoms with energy which then emit photons in a stimulated emission, creating a high-energy concentrated laser beam. This beam is focused on the area to be welded, melting the metals and fusing them together. Key advantages include high weld quality, automation potential, and ability to weld hard to reach areas or dissimilar metals. The high initial costs and specialized equipment and skills required are disadvantages.
The document discusses various topics related to electrical power including:
1) How power is calculated by multiplying voltage by current and is measured in watts. An example is given of calculating the power of a light bulb.
2) How energy is calculated by multiplying power by time and is measured in kilowatt hours. An example is provided of calculating the energy usage of an electric water heater.
3) Safety issues like short circuits, electrical shocks, grounding, fuses, and circuit breakers which protect against too much current and can be reset.
This document describes a mini Tesla coil circuit designed to demonstrate wireless power transmission. It contains an introduction to Tesla coils and their use in wireless power. The circuit diagram and components are listed, including a battery, switch, LED, transistor, resistor, PVC pipe, and copper wire. The working principle of electromagnetic induction is explained, where a varying magnetic field in the primary coil induces a small current in the secondary coil. Advantages include easily transmitting electricity wirelessly without loss, while disadvantages include potential shocks and radio frequency interference. The conclusion restates the objective to demonstrate wireless power transmission using a Tesla coil.
Electromagnetic waves travel at the speed of light through space or a medium. The wavelength and frequency of these waves are inversely related by the formula f*λ = c, where f is frequency, λ is wavelength, and c is the speed of light. For a given medium, the speed of light does not change, so higher frequency waves have shorter wavelengths, and lower frequency waves have longer wavelengths. Electromagnetic fields are present everywhere and invisible to humans. Electric fields are created by voltage differences and magnetic fields are created by electric currents. Both decrease in strength with distance from their source.
The document discusses the history and concepts of wireless power transfer. It began with Nikola Tesla's experiments in 1891 using electromagnetic fields to transmit power through the air over long distances. More recent approaches use magnetic induction through resonant coupling of coils, enabling energy transfer over mid-range distances of around 2 meters. The first wireless lighting experiment conducted by MIT in 2006 demonstrated this principle by powering a light bulb without wires. Wireless power could enable applications like automatically charging devices without plugging them in.
TESLA COIL PHYSICS INVESTIGATORY CLASS 12 CBSEAritraDas50
1. A slayer exciter is an air-cored transformer that steps up a low DC voltage to a high AC voltage, creating an electromagnetic field capable of lighting fluorescent and neon bulbs similar to a Tesla coil.
2. The basic components are a power source, driver circuit, primary coil to create a magnetic field from electricity, secondary coil to step up the voltage, and a top load to increase the electromagnetic field strength.
3. Advantages of wireless electricity transfer via magnetic near fields include high efficiency over distance, the ability to penetrate and wrap around obstacles, and being a non-radiative and safe method of energy transfer for people and animals that can be scaled from milliwatts to kilow
The document discusses electronic sensors and provides examples such as light dependent resistors (LDRs). It describes the key parts of a sensor including the sensing device, processing unit, and output device. It then focuses on LDRs, explaining their construction, characteristics, and how they can be used in a potential divider circuit to measure light intensity.
Christian Oersted discovered that electric currents can produce magnetic effects. He found that a compass needle would move when near a wire with a current running through it, proving that electricity and magnetism are related. A solenoid, which is a coil of wire with an electric current, acts like a magnet and its magnetic field can be controlled by turning the current on and off or changing its strength and direction. An electromagnet uses a solenoid wrapped around a ferromagnetic core, which increases the magnetic field strength produced. Common examples of electromagnets include doorbells, cranes, and devices that record audio, video, and other data to magnetic tapes and disks.
This document contains instructions to match phases on the left with correct statements on the right about how solar cells work. It discusses matching terms like "photovoltaic effect", converting sunlight to electrons, and changing direct current to alternating current used to power appliances.
The document describes direct sensing using light dependent resistors (LDRs), which are sensors whose resistance decreases when exposed to light. An LDR contains a thin film of cadmium sulfide that allows more current to flow when photons hit it and remove electrons. The document explains how LDRs can be used in a potential divider circuit to produce an output voltage that varies with light intensity measured by the LDR.
Resistance is a property that restricts electric current flow through a component. The energy from the voltage drives current through the component, appearing as heat. Resistance is measured in ohms, often given in kilo- and mega-ohms for electronics. When resistors are connected in series, their combined resistance equals the sum of individual resistances, while resistors in parallel have lower combined resistance calculated using reciprocal equations. Materials can be conductors, semiconductors, or insulators depending on their resistance properties.
This study examines the impact of resistance and non-resistance discharge circuits on power consumption in wire cut electric discharge machining (WEDM). The researchers found that non-resistance circuits consume less power than resistance circuits, with savings of up to 6 kilowatt-hours after 7 hours of machining. Non-resistance circuits also recycle and reuse energy discharged through the workpiece and electrode, reducing power consumption by 10-20% compared to traditional resistance circuits. The study concludes that non-resistance circuits significantly reduce power usage and temperature generation during long-duration WEDM processes.
Power is defined as the rate at which energy is converted and is measured in watts. During energy conversion in electrical devices, some input energy is converted to heat. This heating can cause problems in devices like motors and transformers. However, heating is rarely a problem in devices like lamps. As voltage increases for a fixed resistance, current and power output will both increase due to their relationships as defined by Ohm's and Joule's laws.
Electricity is generated through natural phenomena like lightning and man-made devices like windmills. Conductors are materials that allow negatively charged particles called electrons to move through them easily, while insulators like rubber prevent electron flow. Care must be taken when dealing with electricity.
Electricity can be dangerous and hurt people if they touch power lines or are outside during storms with lightning. Wind and dams can be used to generate electricity which is then carried through power lines, so people need to stay away from those to avoid getting hurt.
The document discusses basic electrical wiring and safety. It notes that approximately 290 people die from accidental electrocutions each year in the US, while another 800 die in fires caused by faulty electrical systems. Thousands more are injured. The document then defines electricity as the flow of electrons in a conductor, and notes there are two types of current: direct and alternating. It explains electrical service into homes and businesses, service panels, circuit breakers, cable types, common symbols used in diagrams, and basic receptacle wiring.
The document discusses the working of a light dependent resistor (LDR) and designing a circuit to demonstrate its varying resistance. It begins by introducing LDRs and explaining that their resistivity decreases when light is absorbed. It then describes building a circuit using an LDR, resistor, battery, LED, and breadboard. The circuit works by changing the LDR's resistance based on light intensity, which controls current flow through the LED. Finally, applications of LDRs include light sensors for street lamps, alarms, and automatic controls that require detecting light levels.
This document discusses nuclear fusion as a source of energy. It provides an overview of fusion, including what it is, the conditions needed to achieve it, and its safety advantages over other energy sources. ITER is introduced as a large-scale international project working to develop fusion as an energy source. Key points covered include how deuterium and tritium are used as fuel, the extremely high temperatures required to fuse atomic nuclei, and how magnetic confinement is used to control the plasma within the reactor.
Wireless power Transmission is the process of transferring the electrical energy from one place to another place without use of any wire or cord or cable. It requires resonating coupling between two points called source and destination.
F. Magnetron Deconstruction and Antenna AdaptationKurt Zeller
1) The document discusses deconstructing magnetrons from microwave ovens to use their resonant cavities and tap wires as antennas for experimentation.
2) Connecting the tap wire to an SMA connector was difficult due to material incompatibilities between the copper cavity and stainless steel panel mount.
3) Simulating the magnetron output in EM Pro software proved too complex, so plane wave simulations were used instead. Reducing the magnetron's 900-1000W output power was also explored through circuit designs.
This document outlines the tentative agendas for three introductory training sessions on electronics and electromagnetics simulation using ANSYS software: SIwave, HFSS, and Maxwell. Each session includes morning and afternoon blocks with lectures and workshops covering various simulation topics like import processes, s-parameters, impedance profiles, signal integrity, electromagnetic interference, eigenmodes, meshing, optimization, transient analysis, magnetostatics, electrostatics, eddy currents, magnetic transients, parametric analysis, and multiphysics coupling. Coffee breaks separate the morning and afternoon portions.
Iwt unit 5 laser beam welding sushant bhattSRMUBarabanki
Laser beam welding uses a concentrated coherent light beam to produce coalescence of materials. It works by exciting atoms with energy which then emit photons in a stimulated emission, creating a high-energy concentrated laser beam. This beam is focused on the area to be welded, melting the metals and fusing them together. Key advantages include high weld quality, automation potential, and ability to weld hard to reach areas or dissimilar metals. The high initial costs and specialized equipment and skills required are disadvantages.
The document discusses various topics related to electrical power including:
1) How power is calculated by multiplying voltage by current and is measured in watts. An example is given of calculating the power of a light bulb.
2) How energy is calculated by multiplying power by time and is measured in kilowatt hours. An example is provided of calculating the energy usage of an electric water heater.
3) Safety issues like short circuits, electrical shocks, grounding, fuses, and circuit breakers which protect against too much current and can be reset.
This document describes a mini Tesla coil circuit designed to demonstrate wireless power transmission. It contains an introduction to Tesla coils and their use in wireless power. The circuit diagram and components are listed, including a battery, switch, LED, transistor, resistor, PVC pipe, and copper wire. The working principle of electromagnetic induction is explained, where a varying magnetic field in the primary coil induces a small current in the secondary coil. Advantages include easily transmitting electricity wirelessly without loss, while disadvantages include potential shocks and radio frequency interference. The conclusion restates the objective to demonstrate wireless power transmission using a Tesla coil.
Electromagnetic waves travel at the speed of light through space or a medium. The wavelength and frequency of these waves are inversely related by the formula f*λ = c, where f is frequency, λ is wavelength, and c is the speed of light. For a given medium, the speed of light does not change, so higher frequency waves have shorter wavelengths, and lower frequency waves have longer wavelengths. Electromagnetic fields are present everywhere and invisible to humans. Electric fields are created by voltage differences and magnetic fields are created by electric currents. Both decrease in strength with distance from their source.
The document discusses the history and concepts of wireless power transfer. It began with Nikola Tesla's experiments in 1891 using electromagnetic fields to transmit power through the air over long distances. More recent approaches use magnetic induction through resonant coupling of coils, enabling energy transfer over mid-range distances of around 2 meters. The first wireless lighting experiment conducted by MIT in 2006 demonstrated this principle by powering a light bulb without wires. Wireless power could enable applications like automatically charging devices without plugging them in.
TESLA COIL PHYSICS INVESTIGATORY CLASS 12 CBSEAritraDas50
1. A slayer exciter is an air-cored transformer that steps up a low DC voltage to a high AC voltage, creating an electromagnetic field capable of lighting fluorescent and neon bulbs similar to a Tesla coil.
2. The basic components are a power source, driver circuit, primary coil to create a magnetic field from electricity, secondary coil to step up the voltage, and a top load to increase the electromagnetic field strength.
3. Advantages of wireless electricity transfer via magnetic near fields include high efficiency over distance, the ability to penetrate and wrap around obstacles, and being a non-radiative and safe method of energy transfer for people and animals that can be scaled from milliwatts to kilow
The document discusses electronic sensors and provides examples such as light dependent resistors (LDRs). It describes the key parts of a sensor including the sensing device, processing unit, and output device. It then focuses on LDRs, explaining their construction, characteristics, and how they can be used in a potential divider circuit to measure light intensity.
Christian Oersted discovered that electric currents can produce magnetic effects. He found that a compass needle would move when near a wire with a current running through it, proving that electricity and magnetism are related. A solenoid, which is a coil of wire with an electric current, acts like a magnet and its magnetic field can be controlled by turning the current on and off or changing its strength and direction. An electromagnet uses a solenoid wrapped around a ferromagnetic core, which increases the magnetic field strength produced. Common examples of electromagnets include doorbells, cranes, and devices that record audio, video, and other data to magnetic tapes and disks.
This document contains instructions to match phases on the left with correct statements on the right about how solar cells work. It discusses matching terms like "photovoltaic effect", converting sunlight to electrons, and changing direct current to alternating current used to power appliances.
The document describes direct sensing using light dependent resistors (LDRs), which are sensors whose resistance decreases when exposed to light. An LDR contains a thin film of cadmium sulfide that allows more current to flow when photons hit it and remove electrons. The document explains how LDRs can be used in a potential divider circuit to produce an output voltage that varies with light intensity measured by the LDR.
Resistance is a property that restricts electric current flow through a component. The energy from the voltage drives current through the component, appearing as heat. Resistance is measured in ohms, often given in kilo- and mega-ohms for electronics. When resistors are connected in series, their combined resistance equals the sum of individual resistances, while resistors in parallel have lower combined resistance calculated using reciprocal equations. Materials can be conductors, semiconductors, or insulators depending on their resistance properties.
This study examines the impact of resistance and non-resistance discharge circuits on power consumption in wire cut electric discharge machining (WEDM). The researchers found that non-resistance circuits consume less power than resistance circuits, with savings of up to 6 kilowatt-hours after 7 hours of machining. Non-resistance circuits also recycle and reuse energy discharged through the workpiece and electrode, reducing power consumption by 10-20% compared to traditional resistance circuits. The study concludes that non-resistance circuits significantly reduce power usage and temperature generation during long-duration WEDM processes.
Power is defined as the rate at which energy is converted and is measured in watts. During energy conversion in electrical devices, some input energy is converted to heat. This heating can cause problems in devices like motors and transformers. However, heating is rarely a problem in devices like lamps. As voltage increases for a fixed resistance, current and power output will both increase due to their relationships as defined by Ohm's and Joule's laws.
Electricity is generated through natural phenomena like lightning and man-made devices like windmills. Conductors are materials that allow negatively charged particles called electrons to move through them easily, while insulators like rubber prevent electron flow. Care must be taken when dealing with electricity.
Electricity can be dangerous and hurt people if they touch power lines or are outside during storms with lightning. Wind and dams can be used to generate electricity which is then carried through power lines, so people need to stay away from those to avoid getting hurt.
Electricity can be dangerous and cause burns or shocks, but it is also harnessed through structures like the Hoover Dam which uses water power and wind mills to generate electricity, while lightning is a natural form of electric current and flashlights provide light when other power goes out.
A light bulb is powered by electricity from power lines, which brings electricity to houses and allows a light bulb to turn on when electricity is attracted to the metal filament inside but not the rubber base preventing shocks.
Electricity allows lighting to power homes and devices. Lightning causes loud noises when it strikes while power lines can shock if touched. Switches control the flow of electricity to turn items on like light bulbs and computers.
Power lines distribute electricity from various natural sources like windmills to homes, but can be dangerous if touched. Electricity is generated from different natural sources in the earth and transmitted through power lines, while windmills also produce electricity that is used by consumers. Power lines carry electricity but should be avoided after storms when they could be damaged.
The document contains syllable patterns for various words like bottle, candle, bundle, able, cuddle, struggle, whistle, cradle, table, and simple. It also includes sentences demonstrating the use of these words. There is a short rhyming poem about a little red apple hanging from a tree that drops on a child's nose when asked to come down.
Electricity can be dangerous during storms so it's best to stay inside away from anything related to electricity like light poles. Lightning strikes are very fast and while colorful pictures of lightning may look cute, it is still dangerous. Light poles have insulators on them but during storms it's safest to avoid them.
Social networking sites like Facebook, MySpace, and Twitter allow people to connect and share information online, but they also present some risks if not used carefully. The document discusses both the benefits and drawbacks of social networking and notes that many children, grandchildren, students, and even pets have profiles on these sites.
Electricity flows through wires in houses and uses switches to turn lights on and off through a closed circuit. Conductors like gold, copper and silver allow electricity to flow through them, while insulators like glass and wood do not let electricity pass through. Power from electricity illuminates houses through circuits that provide a complete path for current.
Full-RAG: A modern architecture for hyper-personalizationZilliz
Mike Del Balso, CEO & Co-Founder at Tecton, presents "Full RAG," a novel approach to AI recommendation systems, aiming to push beyond the limitations of traditional models through a deep integration of contextual insights and real-time data, leveraging the Retrieval-Augmented Generation architecture. This talk will outline Full RAG's potential to significantly enhance personalization, address engineering challenges such as data management and model training, and introduce data enrichment with reranking as a key solution. Attendees will gain crucial insights into the importance of hyperpersonalization in AI, the capabilities of Full RAG for advanced personalization, and strategies for managing complex data integrations for deploying cutting-edge AI solutions.
GraphRAG for Life Science to increase LLM accuracyTomaz Bratanic
GraphRAG for life science domain, where you retriever information from biomedical knowledge graphs using LLMs to increase the accuracy and performance of generated answers
Climate Impact of Software Testing at Nordic Testing DaysKari Kakkonen
My slides at Nordic Testing Days 6.6.2024
Climate impact / sustainability of software testing discussed on the talk. ICT and testing must carry their part of global responsibility to help with the climat warming. We can minimize the carbon footprint but we can also have a carbon handprint, a positive impact on the climate. Quality characteristics can be added with sustainability, and then measured continuously. Test environments can be used less, and in smaller scale and on demand. Test techniques can be used in optimizing or minimizing number of tests. Test automation can be used to speed up testing.
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
Dr. Sean Tan, Head of Data Science, Changi Airport Group
Discover how Changi Airport Group (CAG) leverages graph technologies and generative AI to revolutionize their search capabilities. This session delves into the unique search needs of CAG’s diverse passengers and customers, showcasing how graph data structures enhance the accuracy and relevance of AI-generated search results, mitigating the risk of “hallucinations” and improving the overall customer journey.
Why You Should Replace Windows 11 with Nitrux Linux 3.5.0 for enhanced perfor...SOFTTECHHUB
The choice of an operating system plays a pivotal role in shaping our computing experience. For decades, Microsoft's Windows has dominated the market, offering a familiar and widely adopted platform for personal and professional use. However, as technological advancements continue to push the boundaries of innovation, alternative operating systems have emerged, challenging the status quo and offering users a fresh perspective on computing.
One such alternative that has garnered significant attention and acclaim is Nitrux Linux 3.5.0, a sleek, powerful, and user-friendly Linux distribution that promises to redefine the way we interact with our devices. With its focus on performance, security, and customization, Nitrux Linux presents a compelling case for those seeking to break free from the constraints of proprietary software and embrace the freedom and flexibility of open-source computing.
In his public lecture, Christian Timmerer provides insights into the fascinating history of video streaming, starting from its humble beginnings before YouTube to the groundbreaking technologies that now dominate platforms like Netflix and ORF ON. Timmerer also presents provocative contributions of his own that have significantly influenced the industry. He concludes by looking at future challenges and invites the audience to join in a discussion.
Observability Concepts EVERY Developer Should Know -- DeveloperWeek Europe.pdfPaige Cruz
Monitoring and observability aren’t traditionally found in software curriculums and many of us cobble this knowledge together from whatever vendor or ecosystem we were first introduced to and whatever is a part of your current company’s observability stack.
While the dev and ops silo continues to crumble….many organizations still relegate monitoring & observability as the purview of ops, infra and SRE teams. This is a mistake - achieving a highly observable system requires collaboration up and down the stack.
I, a former op, would like to extend an invitation to all application developers to join the observability party will share these foundational concepts to build on:
For the full video of this presentation, please visit: https://www.edge-ai-vision.com/2024/06/building-and-scaling-ai-applications-with-the-nx-ai-manager-a-presentation-from-network-optix/
Robin van Emden, Senior Director of Data Science at Network Optix, presents the “Building and Scaling AI Applications with the Nx AI Manager,” tutorial at the May 2024 Embedded Vision Summit.
In this presentation, van Emden covers the basics of scaling edge AI solutions using the Nx tool kit. He emphasizes the process of developing AI models and deploying them globally. He also showcases the conversion of AI models and the creation of effective edge AI pipelines, with a focus on pre-processing, model conversion, selecting the appropriate inference engine for the target hardware and post-processing.
van Emden shows how Nx can simplify the developer’s life and facilitate a rapid transition from concept to production-ready applications.He provides valuable insights into developing scalable and efficient edge AI solutions, with a strong focus on practical implementation.
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.
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.
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.