This document is a seminar report on Li-fi technology submitted by Dhabekar Roshan Vitthalrao in partial fulfillment of a master's degree. It includes an abstract describing Li-fi technology, which uses visible light communication through LED bulbs to transmit data. The report covers the genesis of Li-fi from Dr. Harald Haas's initial demonstration in 2011. It explains how Li-fi works by modulating LED light intensity and discusses applications like use in airports and hospitals free from radio bandwidth limitations. The conclusion is that Li-fi could provide a wireless alternative if practical challenges around line-of-sight transmission can be addressed.
This document provides an overview of Li-Fi technology through a presentation on the topic. It discusses the history of Li-Fi, how it works by transmitting data through LED light, its advantages over Wi-Fi such as higher bandwidth and more secure communication through visible light. Example applications are given such as using traffic lights and street lamps to transmit data. Challenges for Li-Fi are also noted, such as the need for line of sight transmission and potential interference from other light sources.
This document discusses Li-Fi technology, which uses LED light bulbs to transmit data by varying the intensity of light faster than what the human eye can detect. Li-Fi was pioneered in the 1990s and demonstrated by Harald Haas in 2011. It provides several advantages over Wi-Fi such as higher speed potential and no interference with radio frequencies. Li-Fi works by encoding binary data in the on-off states of an LED and can achieve speeds of over 100 Mbps. Potential applications include use in planes, hospitals, and as public internet hotspots through street lamps. However, challenges include light not passing through solid objects and interference from other light sources.
Li-Fi is a new wireless optical networking technology that uses light-emitting diodes (LEDs) for data transmission. It is a faster and more secure alternative to Wi-Fi as it has a larger bandwidth and avoids interference issues. Li-Fi works by transmitting data through the modulation of light from LED bulbs that can be switched on and off very quickly and detected by photodetectors. It has various applications such as in hospitals, planes, and underwater where radio waves are not suitable or restricted. While Li-Fi has advantages over Wi-Fi like higher speeds and security, it also has limitations as it requires line of sight between transmitters and receivers and cannot work through opaque objects.
Li-Fi is a wireless optical networking technology that uses light-emitting diodes (LEDs) for communication. It was invented by Professor Harald Haas and is a faster, more secure, and cheaper alternative to Wi-Fi. Li-Fi uses visible light communication and LED light bulbs to transmit data, allowing for much higher speeds than Wi-Fi. Some challenges remain around light not passing through objects and interference from other light sources, but Li-Fi shows promise for applications like traffic lights, hazardous environments, and undersea use where Wi-Fi cannot reach.
This document is a seminar report on Li-fi technology submitted by Dhabekar Roshan Vitthalrao in partial fulfillment of a master's degree. It includes an abstract describing Li-fi technology, which uses visible light communication through LED bulbs to transmit data. The report covers the genesis of Li-fi from Dr. Harald Haas's initial demonstration in 2011. It explains how Li-fi works by modulating LED light intensity and discusses applications like use in airports and hospitals free from radio bandwidth limitations. The conclusion is that Li-fi could provide a wireless alternative if practical challenges around line-of-sight transmission can be addressed.
This document provides an overview of Li-Fi technology through a presentation on the topic. It discusses the history of Li-Fi, how it works by transmitting data through LED light, its advantages over Wi-Fi such as higher bandwidth and more secure communication through visible light. Example applications are given such as using traffic lights and street lamps to transmit data. Challenges for Li-Fi are also noted, such as the need for line of sight transmission and potential interference from other light sources.
This document discusses Li-Fi technology, which uses LED light bulbs to transmit data by varying the intensity of light faster than what the human eye can detect. Li-Fi was pioneered in the 1990s and demonstrated by Harald Haas in 2011. It provides several advantages over Wi-Fi such as higher speed potential and no interference with radio frequencies. Li-Fi works by encoding binary data in the on-off states of an LED and can achieve speeds of over 100 Mbps. Potential applications include use in planes, hospitals, and as public internet hotspots through street lamps. However, challenges include light not passing through solid objects and interference from other light sources.
Li-Fi is a new wireless optical networking technology that uses light-emitting diodes (LEDs) for data transmission. It is a faster and more secure alternative to Wi-Fi as it has a larger bandwidth and avoids interference issues. Li-Fi works by transmitting data through the modulation of light from LED bulbs that can be switched on and off very quickly and detected by photodetectors. It has various applications such as in hospitals, planes, and underwater where radio waves are not suitable or restricted. While Li-Fi has advantages over Wi-Fi like higher speeds and security, it also has limitations as it requires line of sight between transmitters and receivers and cannot work through opaque objects.
Li-Fi is a wireless optical networking technology that uses light-emitting diodes (LEDs) for communication. It was invented by Professor Harald Haas and is a faster, more secure, and cheaper alternative to Wi-Fi. Li-Fi uses visible light communication and LED light bulbs to transmit data, allowing for much higher speeds than Wi-Fi. Some challenges remain around light not passing through objects and interference from other light sources, but Li-Fi shows promise for applications like traffic lights, hazardous environments, and undersea use where Wi-Fi cannot reach.
The document discusses Li-Fi technology, which uses visible light communication and LED bulbs to transmit data wirelessly. It provides an introduction to Li-Fi, outlines its history starting with its development by Professor Harald Haas, and describes how Li-Fi works and some potential real-world applications. The document also compares Li-Fi to Wi-Fi, noting advantages like high data rates and security due to an inability to penetrate walls, as well as disadvantages such as requiring line of sight and susceptibility to interference from other light sources.
This presentation provides an overview of Li-Fi technology. It discusses how Li-Fi works by transmitting data through illumination by varying the intensity of LED bulbs faster than the human eye can detect. The history and development of Li-Fi is covered, along with its present use as an alternative to Wi-Fi due to issues with radio spectrum capacity and availability. The working process, applications, advantages over Wi-Fi, and challenges of implementing Li-Fi technology are summarized.
This document provides an overview of Li-Fi technology. It discusses how Li-Fi works by using LED light bulbs to transmit data through variations in intensity faster than the human eye can detect. The document outlines the history and founders of Li-Fi, the needs it addresses regarding radio spectrum issues, and compares it to Wi-Fi. It also describes the construction of Li-Fi including its components, the working process, potential applications in various sectors, advantages such as high efficiency and security, and challenges including blockage of light.
Li-Fi is a new technology that uses visible light communication and light-emitting diodes (LEDs) to transmit data wirelessly. It is the optical counterpart to Wi-Fi, transmitting data using light rather than radio waves. Li-Fi can provide much higher speeds than Wi-Fi and has advantages such as no interference with other electronic devices, better security since light cannot pass through walls, and an unlimited number of users without affecting speed. However, it requires line of sight between the transmitter and receiver and is limited by obstructions blocking the light. The document discusses how Li-Fi works, compares it to Wi-Fi, reviews its advantages and disadvantages, and potential applications in areas like hospitals.
This document discusses Li-Fi technology, which uses light from LED bulbs to transmit data wirelessly. It notes that current wireless data techniques use radio spectrum, which is becoming congested. Li-Fi transmits data through variations in light intensity too fast for the human eye to detect. The document outlines how Li-Fi works and its advantages over Wi-Fi, such as higher speeds, better security, and availability in places radio waves can't reach. It also discusses potential applications of Li-Fi and limitations that need to be addressed.
Li-Fi is a visible light communication system that uses LED bulbs to transmit data wirelessly at very high speeds in a similar way to Wi-Fi. It was created by Prof. Harald Haas and industry groups are working to promote it. Li-Fi works by varying the intensity of light from an LED lamp to transmit digital signals. It has advantages over Wi-Fi like higher speeds, more security, and ability to use visible light spectrum. However, it also has disadvantages like limited range and susceptibility to light interference. If developed further, Li-Fi could be used in many applications and help transition to a greener future with wireless connectivity.
Li-Fi uses visible light communication and is a wireless alternative to Wi-Fi. It transmits data through LED light bulbs and can deliver higher speeds than Wi-Fi. Li-Fi works by switching LED lights on and off very fast, with the light signal undetectable to the human eye. It has advantages over Wi-Fi like higher security, more available spectrum, and energy efficiency. However, it requires line of sight between transmitters and receivers and cannot penetrate walls like radio frequency Wi-Fi signals. Potential applications of Li-Fi include use in hospitals, providing internet access, and underwater communications.
Li-Fi is a technology that uses light from LED bulbs to transmit data wirelessly. It was invented in the 1990s by Professor Harald Haas as an alternative to Wi-Fi that uses radio waves. Li-Fi has several advantages over Wi-Fi, including higher speeds, more available spectrum, and better security. It can be used in applications like traffic lights, hospitals, and airplanes to provide high-speed wireless connectivity without interfering with other wireless devices. The future potential of Li-Fi is significant as it could turn any light source into a wireless hotspot.
This document summarizes Li-Fi (Light Fidelity) technology. It was coined by Professor Harald Haas in 2011 as a wireless optical networking technology using light-emitting diodes for illumination and data transmission. Li-Fi provides high-speed bidirectional communication using visible light and is a form of optical wireless communication that is 1000 times faster than Wi-Fi. It works by transmitting data through rapid variations in the intensity of LED light that can then be detected by a photodetector. Potential applications of Li-Fi include use in hospitals, traffic lights to reduce accidents, and radio frequency restricted environments.
Li-Fi is a wireless optical networking technology that uses light-emitting diodes (LEDs) for data transmission. It was invented by Harald Haas at the University of Edinburgh in 2011 as an alternative to Wi-Fi. Li-Fi transmits data through illumination by taking the fiber out of fiber optics and sending data through a LED light bulb. It provides higher speed, more secure data transmission than Wi-Fi as light cannot pass through walls. Potential applications of Li-Fi include use in traffic lights, hospitals, airplanes, and as a means of wireless internet from street lamps. However, challenges remain around interference from external light sources and the need for line of sight transmission.
Li-Fi is a technology that uses light from LED bulbs to transmit data wirelessly. It can provide internet access from any light source at speeds over 100 Mbps. Li-Fi differs from Wi-Fi in that it does not use radio waves but instead transmits data through light waves, allowing for greater bandwidth and no interference. Some potential applications of Li-Fi include use in hospitals, on airplanes, and in power plants where radiowaves are not desirable. However, Li-Fi also faces challenges of requiring line of sight and not being able to penetrate solid objects like walls.
This document provides an overview of Li-Fi technology. It discusses how Li-Fi works by transmitting data through LED light bulbs that vary intensity faster than the human eye can detect. The history and present scenario of Li-Fi are presented, along with its advantages over Wi-Fi such as higher bandwidth and security. Applications are identified in traffic lights, hospitals, airplanes, and undersea. Challenges include need for line of sight and interference from other light sources. The conclusion is that if developed further, every light bulb could function as a wireless hotspot.
The document provides an overview of Li-Fi technology. It begins with an introduction and comparison to Wi-Fi. It then discusses the evolution of Li-Fi and its working components. Li-Fi uses visible light communication and LED bulbs to transmit data wirelessly. It has advantages over Wi-Fi such as higher speeds, more available spectrum, and more secure communication. However, it also has limitations since light cannot penetrate walls and data transmission can be blocked by objects. In conclusion, Li-Fi shows potential for high-speed wireless communication if practical challenges can be addressed.
LI-FI technology uses visible light communication and LED bulbs to transmit data wirelessly. It has several advantages over traditional Wi-Fi, including higher speeds, greater security, and an unregulated spectrum. LI-FI could be used in many applications, such as education, healthcare, aircraft connectivity, and traffic management. Its future scope is promising as every light source could potentially transmit data, providing a cleaner, safer alternative to radio-based communication.
LiFi is a wireless optical networking technology that uses LED lights to transmit data. It was invented by Professor Harald Haas in 2011. LiFi works by using LED bulbs that are fitted with a chip to modulate the light for data transmission, which is received by photoreceptors. It can provide transmission speeds up to 10Gbps, has advantages over WiFi like better security and not interfering with other devices, but challenges include light not passing through objects and high installation costs.
Li-Fi is a wireless optical networking technology that uses light-emitting diodes (LEDs) for data transmission. It was first suggested in 2011 as an alternative to Wi-Fi and has since been proven as a viable technology. Li-Fi transmits data using visible light communication between an LED light bulb and a photodetector. It provides advantages over Wi-Fi such as better security since light cannot pass through walls, higher speed potential, and no radio interference. Main applications of Li-Fi include smart lighting, vehicle transportation, hospitals, and underwater communications.
This document provides an overview of Li-fi technology. Li-fi uses light from LED bulbs to transmit data wirelessly, avoiding limitations of Wi-fi such as interference. It works by varying the intensity of light faster than the human eye can detect. While offering advantages like high speeds and security, Li-fi is currently limited by needing light and high installation costs. However, future developments could see every light bulb act as an internet hotspot, providing a cleaner wireless alternative to radio-based networks.
The document discusses Li-Fi technology, which uses visible light communication to transmit data wirelessly. It provides advantages over Wi-Fi such as higher speed, more secure transmission limited by the range of light, and ability to be integrated into existing lighting infrastructure more cheaply. The document outlines how Li-Fi works, its components, advantages, disadvantages, and potential applications. It concludes that Li-Fi could provide a cleaner, greener and safer wireless alternative to overcome radio spectrum limitations if further developed and integrated into mobile devices and lighting.
This document provides an overview of Li-Fi technology. It discusses how Li-Fi works by transmitting data through LED light bulbs that vary in intensity faster than the human eye can detect. The document outlines the history of Li-Fi development and its implementation which involves an emitter, RF driver, and power supply. It compares Li-Fi to Wi-Fi and lists applications such as in aircraft and hazardous environments. Advantages include larger bandwidth and security, while limitations are not working in the dark and light interference. Future developments could make Li-Fi an efficient alternative to radio-based wireless networks.
Unlock the Future of Search with MongoDB Atlas_ Vector Search Unleashed.pdfMalak Abu Hammad
Discover how MongoDB Atlas and vector search technology can revolutionize your application's search capabilities. This comprehensive presentation covers:
* What is Vector Search?
* Importance and benefits of vector search
* Practical use cases across various industries
* Step-by-step implementation guide
* Live demos with code snippets
* Enhancing LLM capabilities with vector search
* Best practices and optimization strategies
Perfect for developers, AI enthusiasts, and tech leaders. Learn how to leverage MongoDB Atlas to deliver highly relevant, context-aware search results, transforming your data retrieval process. Stay ahead in tech innovation and maximize the potential of your applications.
#MongoDB #VectorSearch #AI #SemanticSearch #TechInnovation #DataScience #LLM #MachineLearning #SearchTechnology
HCL Notes and Domino License Cost Reduction in the World of DLAUpanagenda
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
The document discusses Li-Fi technology, which uses visible light communication and LED bulbs to transmit data wirelessly. It provides an introduction to Li-Fi, outlines its history starting with its development by Professor Harald Haas, and describes how Li-Fi works and some potential real-world applications. The document also compares Li-Fi to Wi-Fi, noting advantages like high data rates and security due to an inability to penetrate walls, as well as disadvantages such as requiring line of sight and susceptibility to interference from other light sources.
This presentation provides an overview of Li-Fi technology. It discusses how Li-Fi works by transmitting data through illumination by varying the intensity of LED bulbs faster than the human eye can detect. The history and development of Li-Fi is covered, along with its present use as an alternative to Wi-Fi due to issues with radio spectrum capacity and availability. The working process, applications, advantages over Wi-Fi, and challenges of implementing Li-Fi technology are summarized.
This document provides an overview of Li-Fi technology. It discusses how Li-Fi works by using LED light bulbs to transmit data through variations in intensity faster than the human eye can detect. The document outlines the history and founders of Li-Fi, the needs it addresses regarding radio spectrum issues, and compares it to Wi-Fi. It also describes the construction of Li-Fi including its components, the working process, potential applications in various sectors, advantages such as high efficiency and security, and challenges including blockage of light.
Li-Fi is a new technology that uses visible light communication and light-emitting diodes (LEDs) to transmit data wirelessly. It is the optical counterpart to Wi-Fi, transmitting data using light rather than radio waves. Li-Fi can provide much higher speeds than Wi-Fi and has advantages such as no interference with other electronic devices, better security since light cannot pass through walls, and an unlimited number of users without affecting speed. However, it requires line of sight between the transmitter and receiver and is limited by obstructions blocking the light. The document discusses how Li-Fi works, compares it to Wi-Fi, reviews its advantages and disadvantages, and potential applications in areas like hospitals.
This document discusses Li-Fi technology, which uses light from LED bulbs to transmit data wirelessly. It notes that current wireless data techniques use radio spectrum, which is becoming congested. Li-Fi transmits data through variations in light intensity too fast for the human eye to detect. The document outlines how Li-Fi works and its advantages over Wi-Fi, such as higher speeds, better security, and availability in places radio waves can't reach. It also discusses potential applications of Li-Fi and limitations that need to be addressed.
Li-Fi is a visible light communication system that uses LED bulbs to transmit data wirelessly at very high speeds in a similar way to Wi-Fi. It was created by Prof. Harald Haas and industry groups are working to promote it. Li-Fi works by varying the intensity of light from an LED lamp to transmit digital signals. It has advantages over Wi-Fi like higher speeds, more security, and ability to use visible light spectrum. However, it also has disadvantages like limited range and susceptibility to light interference. If developed further, Li-Fi could be used in many applications and help transition to a greener future with wireless connectivity.
Li-Fi uses visible light communication and is a wireless alternative to Wi-Fi. It transmits data through LED light bulbs and can deliver higher speeds than Wi-Fi. Li-Fi works by switching LED lights on and off very fast, with the light signal undetectable to the human eye. It has advantages over Wi-Fi like higher security, more available spectrum, and energy efficiency. However, it requires line of sight between transmitters and receivers and cannot penetrate walls like radio frequency Wi-Fi signals. Potential applications of Li-Fi include use in hospitals, providing internet access, and underwater communications.
Li-Fi is a technology that uses light from LED bulbs to transmit data wirelessly. It was invented in the 1990s by Professor Harald Haas as an alternative to Wi-Fi that uses radio waves. Li-Fi has several advantages over Wi-Fi, including higher speeds, more available spectrum, and better security. It can be used in applications like traffic lights, hospitals, and airplanes to provide high-speed wireless connectivity without interfering with other wireless devices. The future potential of Li-Fi is significant as it could turn any light source into a wireless hotspot.
This document summarizes Li-Fi (Light Fidelity) technology. It was coined by Professor Harald Haas in 2011 as a wireless optical networking technology using light-emitting diodes for illumination and data transmission. Li-Fi provides high-speed bidirectional communication using visible light and is a form of optical wireless communication that is 1000 times faster than Wi-Fi. It works by transmitting data through rapid variations in the intensity of LED light that can then be detected by a photodetector. Potential applications of Li-Fi include use in hospitals, traffic lights to reduce accidents, and radio frequency restricted environments.
Li-Fi is a wireless optical networking technology that uses light-emitting diodes (LEDs) for data transmission. It was invented by Harald Haas at the University of Edinburgh in 2011 as an alternative to Wi-Fi. Li-Fi transmits data through illumination by taking the fiber out of fiber optics and sending data through a LED light bulb. It provides higher speed, more secure data transmission than Wi-Fi as light cannot pass through walls. Potential applications of Li-Fi include use in traffic lights, hospitals, airplanes, and as a means of wireless internet from street lamps. However, challenges remain around interference from external light sources and the need for line of sight transmission.
Li-Fi is a technology that uses light from LED bulbs to transmit data wirelessly. It can provide internet access from any light source at speeds over 100 Mbps. Li-Fi differs from Wi-Fi in that it does not use radio waves but instead transmits data through light waves, allowing for greater bandwidth and no interference. Some potential applications of Li-Fi include use in hospitals, on airplanes, and in power plants where radiowaves are not desirable. However, Li-Fi also faces challenges of requiring line of sight and not being able to penetrate solid objects like walls.
This document provides an overview of Li-Fi technology. It discusses how Li-Fi works by transmitting data through LED light bulbs that vary intensity faster than the human eye can detect. The history and present scenario of Li-Fi are presented, along with its advantages over Wi-Fi such as higher bandwidth and security. Applications are identified in traffic lights, hospitals, airplanes, and undersea. Challenges include need for line of sight and interference from other light sources. The conclusion is that if developed further, every light bulb could function as a wireless hotspot.
The document provides an overview of Li-Fi technology. It begins with an introduction and comparison to Wi-Fi. It then discusses the evolution of Li-Fi and its working components. Li-Fi uses visible light communication and LED bulbs to transmit data wirelessly. It has advantages over Wi-Fi such as higher speeds, more available spectrum, and more secure communication. However, it also has limitations since light cannot penetrate walls and data transmission can be blocked by objects. In conclusion, Li-Fi shows potential for high-speed wireless communication if practical challenges can be addressed.
LI-FI technology uses visible light communication and LED bulbs to transmit data wirelessly. It has several advantages over traditional Wi-Fi, including higher speeds, greater security, and an unregulated spectrum. LI-FI could be used in many applications, such as education, healthcare, aircraft connectivity, and traffic management. Its future scope is promising as every light source could potentially transmit data, providing a cleaner, safer alternative to radio-based communication.
LiFi is a wireless optical networking technology that uses LED lights to transmit data. It was invented by Professor Harald Haas in 2011. LiFi works by using LED bulbs that are fitted with a chip to modulate the light for data transmission, which is received by photoreceptors. It can provide transmission speeds up to 10Gbps, has advantages over WiFi like better security and not interfering with other devices, but challenges include light not passing through objects and high installation costs.
Li-Fi is a wireless optical networking technology that uses light-emitting diodes (LEDs) for data transmission. It was first suggested in 2011 as an alternative to Wi-Fi and has since been proven as a viable technology. Li-Fi transmits data using visible light communication between an LED light bulb and a photodetector. It provides advantages over Wi-Fi such as better security since light cannot pass through walls, higher speed potential, and no radio interference. Main applications of Li-Fi include smart lighting, vehicle transportation, hospitals, and underwater communications.
This document provides an overview of Li-fi technology. Li-fi uses light from LED bulbs to transmit data wirelessly, avoiding limitations of Wi-fi such as interference. It works by varying the intensity of light faster than the human eye can detect. While offering advantages like high speeds and security, Li-fi is currently limited by needing light and high installation costs. However, future developments could see every light bulb act as an internet hotspot, providing a cleaner wireless alternative to radio-based networks.
The document discusses Li-Fi technology, which uses visible light communication to transmit data wirelessly. It provides advantages over Wi-Fi such as higher speed, more secure transmission limited by the range of light, and ability to be integrated into existing lighting infrastructure more cheaply. The document outlines how Li-Fi works, its components, advantages, disadvantages, and potential applications. It concludes that Li-Fi could provide a cleaner, greener and safer wireless alternative to overcome radio spectrum limitations if further developed and integrated into mobile devices and lighting.
This document provides an overview of Li-Fi technology. It discusses how Li-Fi works by transmitting data through LED light bulbs that vary in intensity faster than the human eye can detect. The document outlines the history of Li-Fi development and its implementation which involves an emitter, RF driver, and power supply. It compares Li-Fi to Wi-Fi and lists applications such as in aircraft and hazardous environments. Advantages include larger bandwidth and security, while limitations are not working in the dark and light interference. Future developments could make Li-Fi an efficient alternative to radio-based wireless networks.
Unlock the Future of Search with MongoDB Atlas_ Vector Search Unleashed.pdfMalak Abu Hammad
Discover how MongoDB Atlas and vector search technology can revolutionize your application's search capabilities. This comprehensive presentation covers:
* What is Vector Search?
* Importance and benefits of vector search
* Practical use cases across various industries
* Step-by-step implementation guide
* Live demos with code snippets
* Enhancing LLM capabilities with vector search
* Best practices and optimization strategies
Perfect for developers, AI enthusiasts, and tech leaders. Learn how to leverage MongoDB Atlas to deliver highly relevant, context-aware search results, transforming your data retrieval process. Stay ahead in tech innovation and maximize the potential of your applications.
#MongoDB #VectorSearch #AI #SemanticSearch #TechInnovation #DataScience #LLM #MachineLearning #SearchTechnology
HCL Notes and Domino License Cost Reduction in the World of DLAUpanagenda
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
leewayhertz.com-AI in predictive maintenance Use cases technologies benefits ...alexjohnson7307
Predictive maintenance is a proactive approach that anticipates equipment failures before they happen. At the forefront of this innovative strategy is Artificial Intelligence (AI), which brings unprecedented precision and efficiency. AI in predictive maintenance is transforming industries by reducing downtime, minimizing costs, and enhancing productivity.
A Comprehensive Guide to DeFi Development Services in 2024Intelisync
DeFi represents a paradigm shift in the financial industry. Instead of relying on traditional, centralized institutions like banks, DeFi leverages blockchain technology to create a decentralized network of financial services. This means that financial transactions can occur directly between parties, without intermediaries, using smart contracts on platforms like Ethereum.
In 2024, we are witnessing an explosion of new DeFi projects and protocols, each pushing the boundaries of what’s possible in finance.
In summary, DeFi in 2024 is not just a trend; it’s a revolution that democratizes finance, enhances security and transparency, and fosters continuous innovation. As we proceed through this presentation, we'll explore the various components and services of DeFi in detail, shedding light on how they are transforming the financial landscape.
At Intelisync, we specialize in providing comprehensive DeFi development services tailored to meet the unique needs of our clients. From smart contract development to dApp creation and security audits, we ensure that your DeFi project is built with innovation, security, and scalability in mind. Trust Intelisync to guide you through the intricate landscape of decentralized finance and unlock the full potential of blockchain technology.
Ready to take your DeFi project to the next level? Partner with Intelisync for expert DeFi development services today!
Salesforce Integration for Bonterra Impact Management (fka Social Solutions A...Jeffrey Haguewood
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.
Let's Integrate MuleSoft RPA, COMPOSER, APM with AWS IDP along with Slackshyamraj55
Discover the seamless integration of RPA (Robotic Process Automation), COMPOSER, and APM with AWS IDP enhanced with Slack notifications. Explore how these technologies converge to streamline workflows, optimize performance, and ensure secure access, all while leveraging the power of AWS IDP and real-time communication via Slack notifications.
How to Interpret Trends in the Kalyan Rajdhani Mix Chart.pdfChart Kalyan
A Mix Chart displays historical data of numbers in a graphical or tabular form. The Kalyan Rajdhani Mix Chart specifically shows the results of a sequence of numbers over different periods.
Driving Business Innovation: Latest Generative AI Advancements & Success StorySafe Software
Are you ready to revolutionize how you handle data? Join us for a webinar where we’ll bring you up to speed with the latest advancements in Generative AI technology and discover how leveraging FME with tools from giants like Google Gemini, Amazon, and Microsoft OpenAI can supercharge your workflow efficiency.
During the hour, we’ll take you through:
Guest Speaker Segment with Hannah Barrington: Dive into the world of dynamic real estate marketing with Hannah, the Marketing Manager at Workspace Group. Hear firsthand how their team generates engaging descriptions for thousands of office units by integrating diverse data sources—from PDF floorplans to web pages—using FME transformers, like OpenAIVisionConnector and AnthropicVisionConnector. This use case will show you how GenAI can streamline content creation for marketing across the board.
Ollama Use Case: Learn how Scenario Specialist Dmitri Bagh has utilized Ollama within FME to input data, create custom models, and enhance security protocols. This segment will include demos to illustrate the full capabilities of FME in AI-driven processes.
Custom AI Models: Discover how to leverage FME to build personalized AI models using your data. Whether it’s populating a model with local data for added security or integrating public AI tools, find out how FME facilitates a versatile and secure approach to AI.
We’ll wrap up with a live Q&A session where you can engage with our experts on your specific use cases, and learn more about optimizing your data workflows with AI.
This webinar is ideal for professionals seeking to harness the power of AI within their data management systems while ensuring high levels of customization and security. Whether you're a novice or an expert, gain actionable insights and strategies to elevate your data processes. Join us to see how FME and AI can revolutionize how you work with data!
Generating privacy-protected synthetic data using Secludy and MilvusZilliz
During this demo, the founders of Secludy will demonstrate how their system utilizes Milvus to store and manipulate embeddings for generating privacy-protected synthetic data. Their approach not only maintains the confidentiality of the original data but also enhances the utility and scalability of LLMs under privacy constraints. Attendees, including machine learning engineers, data scientists, and data managers, will witness first-hand how Secludy's integration with Milvus empowers organizations to harness the power of LLMs securely and efficiently.
Ivanti’s Patch Tuesday breakdown goes beyond patching your applications and brings you the intelligence and guidance needed to prioritize where to focus your attention first. Catch early analysis on our Ivanti blog, then join industry expert Chris Goettl for the Patch Tuesday Webinar Event. There we’ll do a deep dive into each of the bulletins and give guidance on the risks associated with the newly-identified vulnerabilities.
Skybuffer SAM4U tool for SAP license adoptionTatiana Kojar
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.
Your One-Stop Shop for Python Success: Top 10 US Python Development Providersakankshawande
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.
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.
Nunit vs XUnit vs MSTest Differences Between These Unit Testing Frameworks.pdfflufftailshop
When it comes to unit testing in the .NET ecosystem, developers have a wide range of options available. Among the most popular choices are NUnit, XUnit, and MSTest. These unit testing frameworks provide essential tools and features to help ensure the quality and reliability of code. However, understanding the differences between these frameworks is crucial for selecting the most suitable one for your projects.
9. •Global Mobile Data Traffic in
2015
3.7 Exabytes (3972844748.8
Gigabytes)
•Global Mobile Data Traffic in
2020
30.6 Exabytes
(32856499814.4 Gigabytes)
4/12/2016 Li-Fi: For a Brighter Future 9
10. All of them use
Radio waves
-Most used is the 2.4 Ghz band
4/12/2016 Li-Fi: For a Brighter Future 10
13. Li-Fi
-What is Li-Fi ?
How does it work ?
4/12/2016 Li-Fi: For a Brighter Future 13
14. Li-Fi
4/12/2016 Li-Fi: For a Brighter Future 14
Light Fidelity (Li-Fi)
is a bidirectional, high speed and fully
networked wireless communication
technology similar to Wi-Fi.
Li-Fi is the use of the visible light portion
of the electromagnetic spectrum to
transmit information at very high speeds.
15. How does it work
?
4/12/2016 Li-Fi: For a Brighter Future 15
19. It’s FREE
The visible light frequencies
are not regulated
But in contrast radio
frequencies are.
4/12/2016 Li-Fi: For a Brighter Future 19
20. Li-Fi is about 100 times
faster than average Wi-Fi
speeds
Reaching up to 1 gbps
Highest speed recorded
using Li-Fi is 224 gbps
4/12/2016 Li-Fi: For a Brighter Future 20
21. Visible light spectrum
is 10 000 times larger
than the entire radio
frequency used for
communication
4/12/2016 Li-Fi: For a Brighter Future 21
23. Li - Fi
•Can be used in places
where RF can not be used
Like petro chemical plants
or places where
measurements need to be
taken and monitored4/12/2016 Li-Fi: For a Brighter Future 23
25. Li-Fi is more secure
than Wi-Fi
•Does not penetrate walls
•Each light can have specific
settings
•Suitable for use in closed areas
Offices, Homes, Cafes….
4/12/2016 Li-Fi: For a Brighter Future 25
26. In addition the
infrastructure is
already there
•We use lights for illumination
In the future lights can serve a
dual purpose
1- Illumination
2- Communication
4/12/2016 Li-Fi: For a Brighter Future 26
28. •Traffic systems and Vehicles
•Underwater Data exchange
•Indoor navigation and
information display
• etc.
4/12/2016 Li-Fi: For a Brighter Future 28
32. The Future will be
Bright
4/12/2016 Li-Fi: For a Brighter Future 32
….Literally
33. References
Cisco Visual Networking Index: Global Mobile
Data Traffic Forecast Update, 2015–2020 White
Paper
Purelifi.com
Tam Dalyell Prize Lecture Sunday 13 April at the
University of Edinburgh’s Playfair Library. (2014)
WHO (World Human Organization) International
Agency for Research on Cancer (press release no
209 31st May 2011)
4/12/2016 LI-FI: FOR A BRIGHTER FUTURE 33