After the read, you will learn the characteristics of the 6 wireless protocols IEEE protocols: LoRa, NB-IoT, ZigBee, Wi-Fi, BLE, WiMax.
In the field of IoT, a wide range of communication technologies wireless protocols exist simultaneously. In terms of transmission distance, there are BLE, WI-FI, ZigBee, sub1G, etc., which are widely used in the context of local wireless networks, such as wearable, home, and enterprise applications.
4G is the fourth generation of cellular wireless standards that provides significantly higher bandwidth than 3G. 4G standards, known as IMT-Advanced, require minimum bandwidth of 100 Mbps to support high quality streaming content. Existing 3G technologies like WiMAX and LTE fall short of this requirement. Two competing 4G standards were submitted in 2009: LTE Advanced from 3GPP and 802.16m from IEEE. Both aim to be spectrally efficient and support seamless handovers and high quality of service over all-IP networks. Present implementations of WiMAX and LTE are considered interim solutions until WiMAX 2 and LTE Advanced are finalized to fully meet 4G standards.
4G technology provides very high data transfer rates to both stationary and mobile users, aiming to overcome the speed and quality deficiencies of 3G. 4G can be described as "MAGIC" - Mobile multimedia, Anytime Anywhere, Global mobility support, and integrated/personalized services. Key components that enable 4G networks include OFDMA, MIMO, IPv6, and smart antennas. 4G uses LTE standards and provides significantly higher bandwidth and lower latency than 3G networks.
The document discusses the evolution of mobile cellular communication from 0G to 4G. It provides information on the key characteristics of each generation including:
1) 0G systems used centralized antenna towers with limited channels. 1G introduced cellular divisions allowing frequency reuse.
2) 2G introduced digital standards like GSM, TDMA, and CDMA. 3) 3G networks allowed simultaneous voice and data on the same network.
3) 4G aims to provide speeds over 100Mbps for broadband access. Issues around defining 4G standards and the relative speeds of 3G and 4G networks are also examined.
What are the advantages and disadvantages of the four major wireless technologies Wi-Fi Bluetooth ZigBee and Sub-GHz?
Now there are about 50 billion devices using the four major wireless technologies Wi-Fi Bluetooth ZigBee and Sub-GHz wireless communication methods.
According to data from the GSM Consortium, mobile handhelds and personal computers account for only 1/4 of these devices, and the rest are autonomous interconnected devices that use non-user interaction to communicate with other machines.
At present, our Internet is rapidly developing into a World Wide Web - Internet of Things (IoT) with the interconnection of four major wireless technologies: Wi-Fi Bluetooth ZigBee and Sub-GHz wireless devices.
Wi-Fi Bluetooth ZigBee and Sub-GHz wireless network technology core features and capabilities
Wi-Fi is a communication technology based on a 2.4GHz band, which is good at transmitting large amounts of data quickly between two nodes, but at the same time consumes high energy and limits each AP to no more than 15-32 clients in a star configuration.
Bluetooth is another 2.4GHz technology, which is targeted at portable devices and is mainly used as a point-to-point solution, supporting only a few nodes.
ZigBee shares the same wireless spectrum as Bluetooth and Wi-Fi, but is only used to meet the specific needs of low-power wireless sensor nodes.
What are the advantages and disadvantages of the four major wireless technologies Wi-Fi Bluetooth ZigBee and Sub-GHz?
Now there are about 50 billion devices using the four major wireless technologies Wi-Fi Bluetooth ZigBee and Sub-GHz wireless communication methods.
According to data from the GSM Consortium, mobile handhelds and personal computers account for only 1/4 of these devices, and the rest are autonomous interconnected devices that use non-user interaction to communicate with other machines.
At present, our Internet is rapidly developing into a World Wide Web - Internet of Things (IoT) with the interconnection of four major wireless technologies: Wi-Fi Bluetooth ZigBee and Sub-GHz wireless devices.
This document discusses 4G networks and their evolution. It defines 4G as the next generation of high-speed mobile technologies replacing 3G. Key requirements for 4G include being based on an all-IP packet switched network with peak data rates up to 100Mb/s for high mobility and 1Gb/s for low mobility. The main 4G network types are WiMAX and LTE. Benefits of 4G include faster speeds and better streaming capabilities. The document outlines the growth of 4G globally and its current limited availability in India. Both advantages like increased connectivity and disadvantages like high costs are discussed.
After the read, you will learn the characteristics of the 6 wireless protocols IEEE protocols: LoRa, NB-IoT, ZigBee, Wi-Fi, BLE, WiMax.
In the field of IoT, a wide range of communication technologies wireless protocols exist simultaneously. In terms of transmission distance, there are BLE, WI-FI, ZigBee, sub1G, etc., which are widely used in the context of local wireless networks, such as wearable, home, and enterprise applications.
4G is the fourth generation of cellular wireless standards that provides significantly higher bandwidth than 3G. 4G standards, known as IMT-Advanced, require minimum bandwidth of 100 Mbps to support high quality streaming content. Existing 3G technologies like WiMAX and LTE fall short of this requirement. Two competing 4G standards were submitted in 2009: LTE Advanced from 3GPP and 802.16m from IEEE. Both aim to be spectrally efficient and support seamless handovers and high quality of service over all-IP networks. Present implementations of WiMAX and LTE are considered interim solutions until WiMAX 2 and LTE Advanced are finalized to fully meet 4G standards.
4G technology provides very high data transfer rates to both stationary and mobile users, aiming to overcome the speed and quality deficiencies of 3G. 4G can be described as "MAGIC" - Mobile multimedia, Anytime Anywhere, Global mobility support, and integrated/personalized services. Key components that enable 4G networks include OFDMA, MIMO, IPv6, and smart antennas. 4G uses LTE standards and provides significantly higher bandwidth and lower latency than 3G networks.
The document discusses the evolution of mobile cellular communication from 0G to 4G. It provides information on the key characteristics of each generation including:
1) 0G systems used centralized antenna towers with limited channels. 1G introduced cellular divisions allowing frequency reuse.
2) 2G introduced digital standards like GSM, TDMA, and CDMA. 3) 3G networks allowed simultaneous voice and data on the same network.
3) 4G aims to provide speeds over 100Mbps for broadband access. Issues around defining 4G standards and the relative speeds of 3G and 4G networks are also examined.
What are the advantages and disadvantages of the four major wireless technologies Wi-Fi Bluetooth ZigBee and Sub-GHz?
Now there are about 50 billion devices using the four major wireless technologies Wi-Fi Bluetooth ZigBee and Sub-GHz wireless communication methods.
According to data from the GSM Consortium, mobile handhelds and personal computers account for only 1/4 of these devices, and the rest are autonomous interconnected devices that use non-user interaction to communicate with other machines.
At present, our Internet is rapidly developing into a World Wide Web - Internet of Things (IoT) with the interconnection of four major wireless technologies: Wi-Fi Bluetooth ZigBee and Sub-GHz wireless devices.
Wi-Fi Bluetooth ZigBee and Sub-GHz wireless network technology core features and capabilities
Wi-Fi is a communication technology based on a 2.4GHz band, which is good at transmitting large amounts of data quickly between two nodes, but at the same time consumes high energy and limits each AP to no more than 15-32 clients in a star configuration.
Bluetooth is another 2.4GHz technology, which is targeted at portable devices and is mainly used as a point-to-point solution, supporting only a few nodes.
ZigBee shares the same wireless spectrum as Bluetooth and Wi-Fi, but is only used to meet the specific needs of low-power wireless sensor nodes.
What are the advantages and disadvantages of the four major wireless technologies Wi-Fi Bluetooth ZigBee and Sub-GHz?
Now there are about 50 billion devices using the four major wireless technologies Wi-Fi Bluetooth ZigBee and Sub-GHz wireless communication methods.
According to data from the GSM Consortium, mobile handhelds and personal computers account for only 1/4 of these devices, and the rest are autonomous interconnected devices that use non-user interaction to communicate with other machines.
At present, our Internet is rapidly developing into a World Wide Web - Internet of Things (IoT) with the interconnection of four major wireless technologies: Wi-Fi Bluetooth ZigBee and Sub-GHz wireless devices.
This document discusses 4G networks and their evolution. It defines 4G as the next generation of high-speed mobile technologies replacing 3G. Key requirements for 4G include being based on an all-IP packet switched network with peak data rates up to 100Mb/s for high mobility and 1Gb/s for low mobility. The main 4G network types are WiMAX and LTE. Benefits of 4G include faster speeds and better streaming capabilities. The document outlines the growth of 4G globally and its current limited availability in India. Both advantages like increased connectivity and disadvantages like high costs are discussed.
5G NR technology is too expensive and not suitable for all applications. While it can support data-intensive uses like autonomous vehicles, it may be overkill for some IoT uses. Lower-power WAN technologies like NB-IoT, LTE-M, LoRaWAN and Sigfox are better suited to the low-data, long-battery-life needs of many IoT devices. Additionally, Wi-Fi 6 and the CBRS spectrum provide other connectivity options beyond 5G for both mobile and fixed devices. No single technology is optimal for all situations.
Discover the profound impact of 5G on businesses worldwide. Explore the potential of wireless failover, Gigabit-Class LTE, and mmWave for unparalleled connectivity. Embrace the future with E-Lins Technology.
Digital transformation is at a critical juncture, with a diverse range of industries making changes that signifi-
cantly transform the way people live and work. These shifts have been driving advancements in the financial,
transportation, manufacturing, governmental, and many more sectors. Innovative mobile broadband technologies,
an underlying infrastructure, are a key driving force behind the digitalization of all walks of life. With
the rapid development of 5G, an increasing number of new applications and business models will reshape
the social and economic formation.
Such changes will stimulate strategic planning regarding industry opportunities, technical evolution,
network architecture, and other areas. Telecom operators are growing increasingly concerned with the
creation of a new target network to maximize return on investment (ROI) and achieve business success while
maintaining a competitive edge for the future. Global operators are promoting early deployment of 5G and
innovative business models through continuous 4G evolution. This has led to today's business achievements
and has laid a solid foundation for the huge potential of 5G.
With a gradual consensus being formed for the entire industry, all related players in the industry chain will
develop close collaboration to embrace a brighter future for the wireless network industry.
Continuous 4G evolution, a road to 5G!
4G is the fourth generation of wireless technology that provides faster internet access on mobile devices. It replaces 3G networks and uses technologies like OFDM, MIMO, and IPv6 to transmit data more efficiently. 4G offers theoretical download speeds of up to 1 gigabit per second, allowing users to stream high quality video, use VoIP calling, and access social media with greater ease while on the move. However, 4G also faces limitations including higher data costs, the need for new network infrastructure and 4G-compatible devices, and limited coverage areas compared to 3G networks.
This article talks about Wifi vs LTE technology, what is the difference between Wi-Fi and LTE?
Over the years, the Internet has become increasingly important in our daily lives. Mobile broadband Cellular / LTE and Wi-Fi can be used to access the Internet and perform activities that require a data connection.
Group members: Dilkhusha Ansari, Sidra Najam, Sundus Sami, Anum Haider Rizvi, Syeda Mariam Wadood
The document discusses emerging 4G cellular communication technology. 4G aims to provide ultra-high broadband speeds exceeding 100 Mbps for outdoor use and 1 Gbps for indoor use. It will allow seamless integration of existing networks and technologies to meet increasing user demands for information access anywhere via their mobile devices. Key 4G technologies discussed include OFDM, MIMO, UMTS and TD-SCDMA. Software defined radios and packet switching will allow 4G networks and devices to seamlessly switch between different standards.
This document provides an overview of 5G technology, including its objectives and architecture. 5G is expected to offer data rates over 1 Gbps, support for high capacity and numbers of connections, and new capabilities like integrated access across cell towers and WiFi. It will require integration across standards and a common infrastructure platform. Challenges include integrating various standards and ensuring high redundancy across the core network. 5G networks are expected to launch around 2020 and enable new applications requiring high bandwidth and low latency.
This document provides an overview of 4G wireless technology. It discusses the history and evolution from 1G to 4G networks. 4G is intended to complement and replace 3G systems by providing high-speed internet access and multimedia services over an all-IP network with data rates of at least 100 Mbps for high-mobility communication and 1 Gbps for stationary users. The document outlines key 4G features, standards, objectives, advantages and disadvantages.
The document discusses regulatory spectrum management challenges and actions needed for cellular IoT deployment in Suriname. It notes that some frequency bands assigned for mobile coverage have technology restrictions, and the regulator lacks visibility into spectrum usage. It recommends incentivizing IoT within existing licensing frameworks, following international harmonization, conducting spectrum monitoring, studying IoT technical aspects, and setting up a working group to facilitate IoT innovation. Actions include making spectrum provisions for licensed and unlicensed IoT, preparing for deployment, and identifying future demand bands.
4G is the fourth generation of cellular wireless standards that succeeds 3G and 2G. It is defined as fully packet-switched networks optimized for data delivery with peak speeds of 100 Mbps for mobile users and 1 Gbps for stationary users. 4G offers lower costs, higher data rates, seamless connectivity across networks, and interoperability with existing standards compared to 3G. The key technologies enabling 4G are OFDM, MIMO, and SDR. Potential applications include enhanced mobile gaming, broadband access, virtual presence, personal media repositories, and more.
The modern communication system is aimed to reach the real world one environment from virtual world via connecting resources of one with another through social network system. The communication process is aggravated various infrastructural development to reach in this current level such as 3G and 4G communication system.
The term 4G is used by several types of broadband wireless access communication systems, not only cellular telephone systems. One of the terms used to describe 4G is MAGIC—Mobile multimedia, anytime anywhere, Global mobility support, integrated wireless solution, and customized personal service. As a promise for the future, 4G
systems, that is, cellular broadband wireless access systems have been attracting much interest in the mobile communication arena. The 4G systems not only will support the next generation of mobile service, but also will support the fixed wireless networks. This article presents an overall vision of the 4G features, framework, and integration of mobile communication.
4G is the fourth generation of wireless network technology that will provide significantly higher data transmission speeds than 3G. 4G will be based entirely on IP packet switching and aims to provide transmission speeds of 20-100 Mbps for mobile users. It will utilize technologies like OFDM to maximize speed and minimize interference. 4G will allow for a wide range of applications including high quality video streaming to mobile devices and provide seamless connectivity for users on the go. Some challenges to implementing 4G networks include managing handoffs between networks, ensuring quality of service, and addressing security issues.
The document discusses several emerging wireless technologies and trends. It begins by stating that Wi-Fi will remain the primary choice for high performance networking in homes and offices, while 5G cellular will act as a supplement for larger sites. It then discusses how vehicle-to-everything wireless and 5G networks will enable connectivity between self-driving cars and infrastructure. Finally, it outlines several other developing wireless technologies like long range wireless power, low power wide area networks, wireless sensing, enhanced location tracking, millimeter waves, backscatter networking, and software defined radio.
Private LTE networks use localized cellular towers to establish private LTE services for areas like factories and stadiums. They offer benefits like coverage, capacity, security and user control compared to public LTE and Wi-Fi. A report predicts the private LTE market will triple by 2025 as 5G and IoT technologies increase demand. Private LTE can be used across industries for applications ranging from manufacturing equipment to airport security and digital signage in smart cities.
5G is coming, but nowadays 4G is still the main trend worldwide. Why 4G network is so important in nowadays? And what advantages does 4G LTE router owns?
IoT Communication Protocols, Socket Programming with Python, MQTT & HTTPAnshu Pandey
Notes on IoT COmmunication protocols like Wifi, Bluetooth, Sigfox, XBee, LoraWAN. A complete description and python code for socket programming, TCP client, and Server, UDP Client, and Server. HTTP v/s MQTT. MQTT Python programming for raspberry pi
What are the differences and relationships between LTE-M and NB-IoT?
What is LTE-M?
LTE-M, or LTE-Machine-to-Machine, is an LTE evolution-based IoT technology, called Low-Cost MTC in R12 and LTE enhanced MTC (eMTC) in R13, designed to meet the needs of IoT devices based on existing LTE carriers.
The full name of eMTC is enhanced Machine-Type Communication. It is the LTE network between machines using LTE communication for the IoT. It is often abbreviated as M2M.
A response to the growing interest in IoT and LPWAN, LTE-M is unique in that it can be very energy efficient and transmit up to 10 bytes of data per day, but can also transmit up to one megabit per second. LTE-M serves a very wide range of use cases.
Let’s start with the “technical” definition. In 2007, ITU defined a new global standard called IMT-Advanced, stating that it will be an IP packet-switched network that uses VoIP instead of separate telephone call channels, like what is used in 3G networks.
In this presentation, we embark on a journey through the evolution of cellular networks, tracing their roots from 1G to the current pinnacle of technology, 5G. We delve into the intricacies of 5G, exploring its foundational principles, technical workings, and the myriad advantages it brings, from lightning-fast data speeds to enabling groundbreaking applications in augmented reality, the Internet of Things, and beyond. However, no exploration of 5G is complete without addressing concerns and misconceptions. We confront conspiracy theories surrounding 5G, including alleged health risks and unfounded associations with the COVID-19 pandemic. By the end, participants will gain a holistic understanding of 5G's transformative potential, appreciating its benefits while dispelling myths that may cloud its advancement.
5G NR technology is too expensive and not suitable for all applications. While it can support data-intensive uses like autonomous vehicles, it may be overkill for some IoT uses. Lower-power WAN technologies like NB-IoT, LTE-M, LoRaWAN and Sigfox are better suited to the low-data, long-battery-life needs of many IoT devices. Additionally, Wi-Fi 6 and the CBRS spectrum provide other connectivity options beyond 5G for both mobile and fixed devices. No single technology is optimal for all situations.
Discover the profound impact of 5G on businesses worldwide. Explore the potential of wireless failover, Gigabit-Class LTE, and mmWave for unparalleled connectivity. Embrace the future with E-Lins Technology.
Digital transformation is at a critical juncture, with a diverse range of industries making changes that signifi-
cantly transform the way people live and work. These shifts have been driving advancements in the financial,
transportation, manufacturing, governmental, and many more sectors. Innovative mobile broadband technologies,
an underlying infrastructure, are a key driving force behind the digitalization of all walks of life. With
the rapid development of 5G, an increasing number of new applications and business models will reshape
the social and economic formation.
Such changes will stimulate strategic planning regarding industry opportunities, technical evolution,
network architecture, and other areas. Telecom operators are growing increasingly concerned with the
creation of a new target network to maximize return on investment (ROI) and achieve business success while
maintaining a competitive edge for the future. Global operators are promoting early deployment of 5G and
innovative business models through continuous 4G evolution. This has led to today's business achievements
and has laid a solid foundation for the huge potential of 5G.
With a gradual consensus being formed for the entire industry, all related players in the industry chain will
develop close collaboration to embrace a brighter future for the wireless network industry.
Continuous 4G evolution, a road to 5G!
4G is the fourth generation of wireless technology that provides faster internet access on mobile devices. It replaces 3G networks and uses technologies like OFDM, MIMO, and IPv6 to transmit data more efficiently. 4G offers theoretical download speeds of up to 1 gigabit per second, allowing users to stream high quality video, use VoIP calling, and access social media with greater ease while on the move. However, 4G also faces limitations including higher data costs, the need for new network infrastructure and 4G-compatible devices, and limited coverage areas compared to 3G networks.
This article talks about Wifi vs LTE technology, what is the difference between Wi-Fi and LTE?
Over the years, the Internet has become increasingly important in our daily lives. Mobile broadband Cellular / LTE and Wi-Fi can be used to access the Internet and perform activities that require a data connection.
Group members: Dilkhusha Ansari, Sidra Najam, Sundus Sami, Anum Haider Rizvi, Syeda Mariam Wadood
The document discusses emerging 4G cellular communication technology. 4G aims to provide ultra-high broadband speeds exceeding 100 Mbps for outdoor use and 1 Gbps for indoor use. It will allow seamless integration of existing networks and technologies to meet increasing user demands for information access anywhere via their mobile devices. Key 4G technologies discussed include OFDM, MIMO, UMTS and TD-SCDMA. Software defined radios and packet switching will allow 4G networks and devices to seamlessly switch between different standards.
This document provides an overview of 5G technology, including its objectives and architecture. 5G is expected to offer data rates over 1 Gbps, support for high capacity and numbers of connections, and new capabilities like integrated access across cell towers and WiFi. It will require integration across standards and a common infrastructure platform. Challenges include integrating various standards and ensuring high redundancy across the core network. 5G networks are expected to launch around 2020 and enable new applications requiring high bandwidth and low latency.
This document provides an overview of 4G wireless technology. It discusses the history and evolution from 1G to 4G networks. 4G is intended to complement and replace 3G systems by providing high-speed internet access and multimedia services over an all-IP network with data rates of at least 100 Mbps for high-mobility communication and 1 Gbps for stationary users. The document outlines key 4G features, standards, objectives, advantages and disadvantages.
The document discusses regulatory spectrum management challenges and actions needed for cellular IoT deployment in Suriname. It notes that some frequency bands assigned for mobile coverage have technology restrictions, and the regulator lacks visibility into spectrum usage. It recommends incentivizing IoT within existing licensing frameworks, following international harmonization, conducting spectrum monitoring, studying IoT technical aspects, and setting up a working group to facilitate IoT innovation. Actions include making spectrum provisions for licensed and unlicensed IoT, preparing for deployment, and identifying future demand bands.
4G is the fourth generation of cellular wireless standards that succeeds 3G and 2G. It is defined as fully packet-switched networks optimized for data delivery with peak speeds of 100 Mbps for mobile users and 1 Gbps for stationary users. 4G offers lower costs, higher data rates, seamless connectivity across networks, and interoperability with existing standards compared to 3G. The key technologies enabling 4G are OFDM, MIMO, and SDR. Potential applications include enhanced mobile gaming, broadband access, virtual presence, personal media repositories, and more.
The modern communication system is aimed to reach the real world one environment from virtual world via connecting resources of one with another through social network system. The communication process is aggravated various infrastructural development to reach in this current level such as 3G and 4G communication system.
The term 4G is used by several types of broadband wireless access communication systems, not only cellular telephone systems. One of the terms used to describe 4G is MAGIC—Mobile multimedia, anytime anywhere, Global mobility support, integrated wireless solution, and customized personal service. As a promise for the future, 4G
systems, that is, cellular broadband wireless access systems have been attracting much interest in the mobile communication arena. The 4G systems not only will support the next generation of mobile service, but also will support the fixed wireless networks. This article presents an overall vision of the 4G features, framework, and integration of mobile communication.
4G is the fourth generation of wireless network technology that will provide significantly higher data transmission speeds than 3G. 4G will be based entirely on IP packet switching and aims to provide transmission speeds of 20-100 Mbps for mobile users. It will utilize technologies like OFDM to maximize speed and minimize interference. 4G will allow for a wide range of applications including high quality video streaming to mobile devices and provide seamless connectivity for users on the go. Some challenges to implementing 4G networks include managing handoffs between networks, ensuring quality of service, and addressing security issues.
The document discusses several emerging wireless technologies and trends. It begins by stating that Wi-Fi will remain the primary choice for high performance networking in homes and offices, while 5G cellular will act as a supplement for larger sites. It then discusses how vehicle-to-everything wireless and 5G networks will enable connectivity between self-driving cars and infrastructure. Finally, it outlines several other developing wireless technologies like long range wireless power, low power wide area networks, wireless sensing, enhanced location tracking, millimeter waves, backscatter networking, and software defined radio.
Private LTE networks use localized cellular towers to establish private LTE services for areas like factories and stadiums. They offer benefits like coverage, capacity, security and user control compared to public LTE and Wi-Fi. A report predicts the private LTE market will triple by 2025 as 5G and IoT technologies increase demand. Private LTE can be used across industries for applications ranging from manufacturing equipment to airport security and digital signage in smart cities.
5G is coming, but nowadays 4G is still the main trend worldwide. Why 4G network is so important in nowadays? And what advantages does 4G LTE router owns?
IoT Communication Protocols, Socket Programming with Python, MQTT & HTTPAnshu Pandey
Notes on IoT COmmunication protocols like Wifi, Bluetooth, Sigfox, XBee, LoraWAN. A complete description and python code for socket programming, TCP client, and Server, UDP Client, and Server. HTTP v/s MQTT. MQTT Python programming for raspberry pi
What are the differences and relationships between LTE-M and NB-IoT?
What is LTE-M?
LTE-M, or LTE-Machine-to-Machine, is an LTE evolution-based IoT technology, called Low-Cost MTC in R12 and LTE enhanced MTC (eMTC) in R13, designed to meet the needs of IoT devices based on existing LTE carriers.
The full name of eMTC is enhanced Machine-Type Communication. It is the LTE network between machines using LTE communication for the IoT. It is often abbreviated as M2M.
A response to the growing interest in IoT and LPWAN, LTE-M is unique in that it can be very energy efficient and transmit up to 10 bytes of data per day, but can also transmit up to one megabit per second. LTE-M serves a very wide range of use cases.
Let’s start with the “technical” definition. In 2007, ITU defined a new global standard called IMT-Advanced, stating that it will be an IP packet-switched network that uses VoIP instead of separate telephone call channels, like what is used in 3G networks.
In this presentation, we embark on a journey through the evolution of cellular networks, tracing their roots from 1G to the current pinnacle of technology, 5G. We delve into the intricacies of 5G, exploring its foundational principles, technical workings, and the myriad advantages it brings, from lightning-fast data speeds to enabling groundbreaking applications in augmented reality, the Internet of Things, and beyond. However, no exploration of 5G is complete without addressing concerns and misconceptions. We confront conspiracy theories surrounding 5G, including alleged health risks and unfounded associations with the COVID-19 pandemic. By the end, participants will gain a holistic understanding of 5G's transformative potential, appreciating its benefits while dispelling myths that may cloud its advancement.
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.
AI 101: An Introduction to the Basics and Impact of Artificial IntelligenceIndexBug
Imagine a world where machines not only perform tasks but also learn, adapt, and make decisions. This is the promise of Artificial Intelligence (AI), a technology that's not just enhancing our lives but revolutionizing entire industries.
Fueling AI with Great Data with Airbyte WebinarZilliz
This talk will focus on how to collect data from a variety of sources, leveraging this data for RAG and other GenAI use cases, and finally charting your course to productionalization.
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.
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).
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.
Best 20 SEO Techniques To Improve Website Visibility In SERPPixlogix Infotech
Boost your website's visibility with proven SEO techniques! Our latest blog dives into essential strategies to enhance your online presence, increase traffic, and rank higher on search engines. From keyword optimization to quality content creation, learn how to make your site stand out in the crowded digital landscape. Discover actionable tips and expert insights to elevate your SEO game.
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
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.
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!
AI-Powered Food Delivery Transforming App Development in Saudi Arabia.pdfTechgropse Pvt.Ltd.
In this blog post, we'll delve into the intersection of AI and app development in Saudi Arabia, focusing on the food delivery sector. We'll explore how AI is revolutionizing the way Saudi consumers order food, how restaurants manage their operations, and how delivery partners navigate the bustling streets of cities like Riyadh, Jeddah, and Dammam. Through real-world case studies, we'll showcase how leading Saudi food delivery apps are leveraging AI to redefine convenience, personalization, and efficiency.
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.
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.
Have you ever been confused by the myriad of choices offered by AWS for hosting a website or an API?
Lambda, Elastic Beanstalk, Lightsail, Amplify, S3 (and more!) can each host websites + APIs. But which one should we choose?
Which one is cheapest? Which one is fastest? Which one will scale to meet our needs?
Join me in this session as we dive into each AWS hosting service to determine which one is best for your scenario and explain why!
Choosing The Best AWS Service For Your Website + API.pptx
4G Industrial router.pdf
1. 4G Industrial router
4G Industrial Router
Accompany with economy’s development, various kinds of industrial devices or CPE
are installed in M2M and IoT. 4G Industrial router is playing a very important role
between these devices, ensuring provide stable data transmission for all the other
devices. There are some points we should know about 4G industrial router.
4G LTE is built in carrier аggrеgаtiоn
Cаrriеr aggregation iѕ the innоvаtivе nеw feature оn which LTE is built. In
соnvеntiоnаl LTE nеtwоrkѕ, саrriеrѕ brоаdсаѕt in multiple frequency bаndѕ, but еасh
dеviсе оr 4G router саn оnlу utilizе a single frеԛuеnсу band аt a timе. At аnу givеn
timе, сеrtаin frequency bands mау bе оvеrtаxеd with trаffiс, while other frequency
bands remain underutilized. Thiѕ means the dеviсеѕ аrе undеr utilizing thе network
rеѕоurсеѕ, and ԛuаlitу-оf-ѕеrviсе (QоS) might be negatively imрасtеd bу high-volume
uѕаgе on one bаnd within a gеоgrарhiс area or when аррliсаtiоnѕ rеԛuirе a lоt of
bаndwidth. Cаrriеr aggregation, however, mаkеѕ it роѕѕiblе for саrriеrѕ tо trаnѕmit
dаtа tо a dеviсе likе a wireless router оvеr multiрlе nеtwоrk bаndѕ at once, through
a ѕinglе “аggrеgаtеd dаtа pipe.”
4G LTE iѕ mоrе reliable
With ѕinglе-bаnd LTE, it iѕ possible fоr соnnесtivitу tо bе intеrruрtеd fоr a fеw
ѕесоndѕ whеn a dеviсе ѕwitсhеѕ frеԛuеnсу bаndѕ. In contrast, bесаuѕе LTE utilizes
multiрlе frequency bands at оnсе, dеviсеѕ ѕwitсh frеԛuеnсу bands in just an fеw
milliseconds. Additiоnаllу, even if оnе bаnd drорѕ, thе device ѕtауѕ соnnесtеd via thе
second bаnd in thе aggregated data pipe.
How to choose 4G industrial router
It mainly depends on your detailed project, you can choose 4G industrial router
based on its interfaces (RJ45 Port, Serial Port, USB Port, DIO Port, and so on),
meanwhile you should consider single sim or dual sim you required. Moreover you
should check your location’s network quality to choose a suitable antenna to install
along with 4G industrial router.
For more information, you can freely check site www.e-lins.com