Qualcomm is developing 5G NR technology to enable a unified 5G air interface that can address diverse spectrum types, services, and deployments. 5G will transform industries and society by connecting billions of devices and delivering new immersive experiences with requirements such as ultra-low latency and ultra-high reliability. Qualcomm is leading innovations for 5G NR such as optimized waveforms, scalable numerology and transmission time interval, efficient spectrum utilization techniques, and support for diverse spectrum bands and deployments.
The proposed new network architecture and the emergence of various types of transmission technology will pose new challenges to 5G air interface technology standardization, program design, and simulation.
For physical layer transmission technology, 5G will introduce new waveform & nonorthogonal multiple access at the physical layer to achieve the required traffic latency in the air interface.
To explore spatial freedom & improve the network throughput, 5G will introduce massive MIMO technology. In the simulation evaluation system, massive MIMO & MU-MIMO technology will greatly increase computational interference complexity.
The new channel propagation model will be introduced based on high-frequency band transmission technology, D2D technology & massive MIMO technology.
Need to design scheduling algorithm for heterogeneous computing resources, accurately estimate the consumed time of heterogeneous computing & interface data transmission and meanwhile design the synchronized mechanism for computing tasks to make full use of heterogeneous computing platform.
https://telcomaglobal.com/p/5g-testing-training-certification
5g technology is a unique combination of high speed internet access , low latency , high reliability & seamless coverage which will support no. of vehicles & transport infrastructure. 5G platform will impact many industries like automotive , entertainment, agriculture , manufacturing and IT. As per the research forecast “IOT will account for one quarter of the global 41 million 5G connections in 2024”, out of these ¾ of the devices will be auto industry via embedded vehicle connections.
There are wide range of applications that will benefit from 5G ultra fast networks and real time responsiveness of the network.These properties of 5G technology are very important for many applications of IOT e.g self driven cars , intelligent transportation which demands very low latency .This will be a great boom for interactive mobile gaming which is bandwidth hungry application. 5G technology enables us to control more devices remotely in various applications where real time network performance is critical, like remote control of vehicles. It focuses on worker safety as well as monitoring environment. 5G technology is not focusing on improving speed , but this will prove best in evolution of business etc. IOT in 5G have excelled in connecting number of phones , tablets and other devices, however connecting cars , meters, sensors require more advanced business models.
5G Network Architecture, Design and Optimisation3G4G
Presented by Prof. Andy Sutton, Principal Network Architect, Architecture & Strategy, TSO, BT at The IET '5G - State of Play' conference on 24th January 2018
*** SHARED WITH PERMISSION ***
Materi seminar 5 g ieee comsoc lecture 5g evolution v2indonesiabelajar
This document discusses 5G evolution and the need for 5G networks. It summarizes the evolution from 1G to 4G mobile networks and some key 4G technologies. It then outlines candidate technologies for 5G such as advanced networking, multi-tier networks, and multi-radio scenarios that could satisfy the growing bandwidth demand, support the Internet of Things, and help operators address the challenge of lower revenue per bit. The document concludes by discussing 5G requirements such as high network capacity and uniform connectivity experience.
Content
Brief history about wireless ecosystem.
What is LTE (Long Term Evolution) ?
How is it different from older technologies ?
Network architecture in LTE
Radio Access network (RAN)
Evolved Packet Core (EPC)
Bearers in LTE
Interfaces in LTE
Life Cycle of a UE
LTE RAN overview
Architecture and requirements
Channel bandwidths and operating bands
OFDMA and SC-FDMA
Frequency (LTE-FDD) and time division duplexing (LTE-TDD)
Multiple Antenna techniques in LTE
Channels in LTE and protocol Stack
LTE EPC overview
Architecture
Functions of various elements in EPC
5G Network - It's Architecture and TechnologyRajKumarRaj32
The document discusses the evolution of mobile network technologies from 1G to 5G. It provides details on the key features and technologies of each generation including network speeds, capabilities and limitations. 5G is described as being able to provide speeds up to 1Gbps using technologies like millimeter waves, small cells, massive MIMO, beamforming and full duplex to help address limitations of previous standards like inability to handle high speeds or pass through obstacles. 5G is predicted to deliver enhanced mobile broadband and help enable new applications.
This document provides an overview of 5G networks including:
- 5G aims to deliver data rates of up to 10 Gbps, 100 Mbps in urban areas, and coverage everywhere with massive device connectivity and reduced power consumption.
- 5G will utilize spectrum from sub-1 GHz to 100 GHz including millimeter wave bands and enable new use cases across industries.
- Standardization is expected to begin in 2016 with commercial launches starting in 2020. Major players are conducting trials and collaborating globally to develop 5G technologies and architectures.
Qualcomm is developing 5G NR technology to enable a unified 5G air interface that can address diverse spectrum types, services, and deployments. 5G will transform industries and society by connecting billions of devices and delivering new immersive experiences with requirements such as ultra-low latency and ultra-high reliability. Qualcomm is leading innovations for 5G NR such as optimized waveforms, scalable numerology and transmission time interval, efficient spectrum utilization techniques, and support for diverse spectrum bands and deployments.
The proposed new network architecture and the emergence of various types of transmission technology will pose new challenges to 5G air interface technology standardization, program design, and simulation.
For physical layer transmission technology, 5G will introduce new waveform & nonorthogonal multiple access at the physical layer to achieve the required traffic latency in the air interface.
To explore spatial freedom & improve the network throughput, 5G will introduce massive MIMO technology. In the simulation evaluation system, massive MIMO & MU-MIMO technology will greatly increase computational interference complexity.
The new channel propagation model will be introduced based on high-frequency band transmission technology, D2D technology & massive MIMO technology.
Need to design scheduling algorithm for heterogeneous computing resources, accurately estimate the consumed time of heterogeneous computing & interface data transmission and meanwhile design the synchronized mechanism for computing tasks to make full use of heterogeneous computing platform.
https://telcomaglobal.com/p/5g-testing-training-certification
5g technology is a unique combination of high speed internet access , low latency , high reliability & seamless coverage which will support no. of vehicles & transport infrastructure. 5G platform will impact many industries like automotive , entertainment, agriculture , manufacturing and IT. As per the research forecast “IOT will account for one quarter of the global 41 million 5G connections in 2024”, out of these ¾ of the devices will be auto industry via embedded vehicle connections.
There are wide range of applications that will benefit from 5G ultra fast networks and real time responsiveness of the network.These properties of 5G technology are very important for many applications of IOT e.g self driven cars , intelligent transportation which demands very low latency .This will be a great boom for interactive mobile gaming which is bandwidth hungry application. 5G technology enables us to control more devices remotely in various applications where real time network performance is critical, like remote control of vehicles. It focuses on worker safety as well as monitoring environment. 5G technology is not focusing on improving speed , but this will prove best in evolution of business etc. IOT in 5G have excelled in connecting number of phones , tablets and other devices, however connecting cars , meters, sensors require more advanced business models.
5G Network Architecture, Design and Optimisation3G4G
Presented by Prof. Andy Sutton, Principal Network Architect, Architecture & Strategy, TSO, BT at The IET '5G - State of Play' conference on 24th January 2018
*** SHARED WITH PERMISSION ***
Materi seminar 5 g ieee comsoc lecture 5g evolution v2indonesiabelajar
This document discusses 5G evolution and the need for 5G networks. It summarizes the evolution from 1G to 4G mobile networks and some key 4G technologies. It then outlines candidate technologies for 5G such as advanced networking, multi-tier networks, and multi-radio scenarios that could satisfy the growing bandwidth demand, support the Internet of Things, and help operators address the challenge of lower revenue per bit. The document concludes by discussing 5G requirements such as high network capacity and uniform connectivity experience.
Content
Brief history about wireless ecosystem.
What is LTE (Long Term Evolution) ?
How is it different from older technologies ?
Network architecture in LTE
Radio Access network (RAN)
Evolved Packet Core (EPC)
Bearers in LTE
Interfaces in LTE
Life Cycle of a UE
LTE RAN overview
Architecture and requirements
Channel bandwidths and operating bands
OFDMA and SC-FDMA
Frequency (LTE-FDD) and time division duplexing (LTE-TDD)
Multiple Antenna techniques in LTE
Channels in LTE and protocol Stack
LTE EPC overview
Architecture
Functions of various elements in EPC
5G Network - It's Architecture and TechnologyRajKumarRaj32
The document discusses the evolution of mobile network technologies from 1G to 5G. It provides details on the key features and technologies of each generation including network speeds, capabilities and limitations. 5G is described as being able to provide speeds up to 1Gbps using technologies like millimeter waves, small cells, massive MIMO, beamforming and full duplex to help address limitations of previous standards like inability to handle high speeds or pass through obstacles. 5G is predicted to deliver enhanced mobile broadband and help enable new applications.
This document provides an overview of 5G networks including:
- 5G aims to deliver data rates of up to 10 Gbps, 100 Mbps in urban areas, and coverage everywhere with massive device connectivity and reduced power consumption.
- 5G will utilize spectrum from sub-1 GHz to 100 GHz including millimeter wave bands and enable new use cases across industries.
- Standardization is expected to begin in 2016 with commercial launches starting in 2020. Major players are conducting trials and collaborating globally to develop 5G technologies and architectures.
Content
Brief history about wireless ecosystem.
What is LTE (Long Term Evolution) ?
How is it different from older technologies ?
Network architecture in LTE
Radio Access network (RAN)
Evolved Packet Core (EPC)
Bearers in LTE
Interfaces in LTE
Life Cycle of a UE
LTE RAN overview
Architecture and requirements
Channel bandwidths and operating bands
OFDMA and SC-FDMA
Frequency (LTE-FDD) and time division duplexing (LTE-TDD)
Multiple Antenna techniques in LTE
Channels in LTE and protocol Stack
LTE EPC overview
Architecture
Functions of various elements in EPC
Read other blog posts by the author, Zahid Ghadialy, here: https://communities.cisco.com/people/ZahidGhadialy/content
For more discussions and topics around SP Mobility, please visit our Mobility Community: http://cisco.com/go/mobilitycommunity
Prof. Andy Sutton: 5G RAN Architecture Evolution - Jan 20193G4G
This presentation explores the evolution of GSM, UMTS and LTE radio access network architectures before a detailed review of the RAN architecture options for 5G. The functional decomposition of the 5G radio access network presents the network designer with many challenges with regards placement of RU, DU and CU nodes, all of which are discussed. The presentation concludes with a review of BT UK plans for 5G launch with a fully distributed RAN in support of an EN-DC architecture.
Presented by Professor Andy Sutton CEng FIET, Principal Network Architect, Architecture & Strategy, BT Technology at IET 5G - the Advent conference on 30 January 2019 | IET London: Savoy Place
*** SHARED WITH PERMISSION ***
NB-IoT: a sustainable technology for connecting billions of devicesEricsson
Under the umbrella of 3GPP, radio-access technologies for mobile broadband have evolved effectively to provide connectivity to billions of subscribers and things. Within this ecosystem, the standardization of a radio technology for massive MTC applications – narrowband IoT (NB-IoT) – is also evolving. The aim is for this technology to provide cost-effective connectivity to billions of IoT devices, supporting low power consumption, the use of low-cost devices, and provision of excellent coverage – all rolled out as software on top of existing LTE infrastructure. The design of NB-IoT mimics that of LTE, facilitating radio network evolution and efficient coexistence with MBB, reducing time to market, and reaping the benefits of standardization and economies of scale.
The IoT embeds a broad range of MTC applications, and among the different types, massive MTC – including applications like smart metering, agriculture and real estate monitoring – sets a number of performance targets for connectivity. Attempting to meet these IoT targets using a radio-access technology designed for mobile broadband, however, doesn't make economic sense. Networks that provide connectivity to massive MTC applications need a radio-access technology that can deliver widespread coverage and low power consumption, often in signal-challenged locations. Hence the need for narrowband-IoT (NB-IoT).
NB-IoT is a 3GPP radio-access technology designed to meet the connectivity requirements for massive MTC applications, as well as the design targets for IoT including low device cost, extended coverage, 40 devices per household, long battery life, and uplink latency of under 10 seconds.
NB-IoT enjoys all the benefits of licensed spectrum, the feature richness of EPC, and the overall ecosystem spread of 3GPP. At the same time, NB-IoT has been designed to meet the challenging TCO structure of the IoT market.
This articles reveals how NB-IoT is being designed and how it can be deployed in GSM spectrum, within an LTE carrier, or in an LTE or WCDMA guard band.
3GPP/GSMA technologies for LPWAN in the Licensed SpectrumTiE Bangalore
1) The document discusses 3GPP/GSMA technologies for low-power wide-area networks (LPWAN) in licensed spectrum, including Narrowband IoT (NB-IoT), LTE-M, and EC-GSM.
2) These technologies aim to provide long battery life, low device cost, extended coverage, and support for various traffic patterns including non-IP and IP traffic using techniques like power saving modes and signal repetition.
3) They operate within licensed cellular bands and core network to provide global connectivity, but require a minimum 200kHz spectrum allocation which limits private networks.
Long Term Evolution (LTE) is the next generation of mobile broadband technology that provides higher data rates and network throughput compared to 3G. LTE networks use OFDM and SC-FDMA for downlink and uplink, respectively, along with MIMO and an all-IP architecture to improve performance. The network elements include eNBs, SGWs, PDN GWs and MMEs. For operators, LTE provides an opportunity to increase ARPU through new applications and services while decreasing CCPU through an all-IP infrastructure. Mass deployment of LTE is expected to begin around 2012, with LTE Advanced enabling data rates up to 1 Gbps.
The document discusses Qualcomm Technologies' role in connecting the Internet of Things through cellular technologies like LTE Cat-M1 and NB-IoT. It outlines how these new narrowband LTE technologies optimize cellular to address a wide range of IoT use cases in a low-cost and low-power way while leveraging existing LTE infrastructure. The technologies are designed to deliver benefits like multi-year battery life, ubiquitous coverage including deeper indoor coverage, and support for massive numbers of devices connecting in a heterogeneous connectivity landscape.
5G will be much more than just a new generation with faster peak rates. We are building a unified, more capable 5G platform to connect new industries, enable new services and empower new user experiences. This presentation details the key components for designing the unified, more capable 5G platform featuring an OFDM-based unified air interface. Learn about the key technology enablers for the 5G platform, and see how we are pioneering many of these technologies today with LTE Advanced and Wi-Fi.
For more information on 5G technologies, use cases and timelines, please visit us at www.qualcomm.com/5G.
Examining the Role of SDN and NFV in the Move Towards LTE-A and 5th Generation Alberto Boaventura
This document discusses the roles of SDN and NFV in enabling 5G/LTE-A networks. SDN and NFV can help address challenges of increasing traffic capacity demands through network functions virtualization and software-defined control of network resources. This allows dynamic allocation of resources through network slicing and virtualization. SDN control can also help with interference avoidance through coordination of resources across virtual base stations in a centralized RAN architecture. Overall, SDN and NFV provide mechanisms for elastic, on-demand provisioning of network capacity needed to support the high traffic demands of evolving 5G technologies.
1) 5G shared spectrum technologies pioneered by Qualcomm such as LTE-U, LAA, LWA and MulteFire can unlock unused spectrum and improve spectrum utilization.
2) Qualcomm has contributed significantly to shared spectrum standards like CBRS and is a founder of alliances to develop shared spectrum technologies.
3) 5G New Radio is being designed by Qualcomm to support flexible deployment in shared, licensed, and unlicensed spectrum bands using technologies like LAA and MulteFire.
Rec 12 073 Lte Small Cells Presentation ArrowsAdrian Treacy
Telefonica UK conducted LTE trials in 2009 in Slough, UK to test the performance of LTE technology. The trials aimed to understand coverage, capacity, mobility and user experience on LTE. Key results included achieving peak downlink speeds of 135Mbps and average cell throughput of 25Mbps with LTE, compared to 2-3Mbps on HSPA networks. LTE also showed high mobility performance with over 99.9% success between LTE cells and low interruption times. The trials provided learning for Telefonica on LTE network planning, deployment and optimization.
Propelling 5G forward: a closer look at 3GPP Release-16Qualcomm Research
This presentation summarizes the 3GPP 5G NR Release 16 projects, including eMBB enhancements, unlicensed, sidelink, IAB, TSN, eURLLC, private networks, C-V2X, and more...
Qualcomm Technologies presented potential 5G use cases and characteristics. 5G is targeting a range of services including enhanced mobile broadband, wide area IoT, high reliability, and smart cities. It will utilize improved RF capabilities, virtualized network elements, and new air interface designs using new spectrum such as mmWave bands and massive MIMO. 5G aims to deliver improved user experience, coverage, cost efficiency, and new services across diverse topologies and cell sizes through a unified design approach across spectrum types and bands.
5g technology is a unique combination of high speed internet access , low latency , high reliability & seamless coverage which will support no. of vehicles & transport infrastructure. 5G platform will impact many industries like automotive , entertainment, agriculture , manufacturing and IT. As per the research forecast “IOT will account for one quarter of the global 41 million 5G connections in 2024”, out of these ¾ of the devices will be auto industry via embedded vehicle connections.
There are wide range of applications that will benefit from 5G ultra fast networks and real time responsiveness of the network.These properties of 5G technology are very important for many applications of IOT e.g self driven cars , intelligent transportation which demands very low latency .This will be a great boom for interactive mobile gaming which is bandwidth hungry application. 5G technology enables us to control more devices remotely in various applications where real time network performance is critical, like remote control of vehicles. It focuses on worker safety as well as monitoring environment. 5G technology is not focusing on improving speed , but this will prove best in evolution of business etc. IOT in 5G have excelled in connecting number of phones , tablets and other devices, however connecting cars , meters, sensors require more advanced business models.
Migration to 5G and Deployment Training and certification by TELCOMA GlobalGaganpreet Singh Walia
5G technology enables enhanced mobile broadband services, which offers higher data rates, lower latency and more capacity. Development of 5G technology is being led by companies such as Huawei, Intel and Qualcomm for modem technology. Lenovo, Nokia, Ericsson, ZTE, Cisco and Samsung is working on infrastructure.
For deployment of 5G, 3GPP is defining new core network as well as new radio access network. New core network of 5G is 5GC and new radio access technology called “5G NR” new radio.5G use cases are already being built around immersive sports viewing and augmented reality applications.
The document provides an overview of 5G technology. It discusses how 5G networks will be able to handle 10,000 times more call and data traffic than 4G and have data download speeds several hundred times faster than 4G. It also outlines the evolution from 1G to 5G mobile networks and compares key features. The architecture of 5G is explained, including the radio access network and 5G nanocore. Functional aspects like quality of service classes and reference points are also summarized.
This document discusses the intersection of 5G networks and open reference platforms. Open reference platforms using disaggregated RAN architectures and open interfaces can offer new user experiences through edge computing and adaptive analytics. Challenges include developing principles for graph abstraction of radio networks and understanding service layers and multi-tenancy in open and democratized architectures. Open source communities and standards bodies are collaborating on initiatives like O-RAN and ONAP to define open interfaces and platforms that enable a more programmable radio access network.
AT&T View on LTE to 5G Network Migration Eiko Seidel
AT&T proposes a three step approach to evolving 5G architecture from early deployment to more mature phases:
1) Early 5G deployment using Phase 1 Option 3 architecture.
2) Phase 1 evolution to Option 7 architecture while still supporting Option 3, through software upgrades.
3) Phase 2 evolution to Option 2/4 architecture while still supporting Options 3 and 7, with specifications that allow different architectures to coexist.
This document provides an overview of LTE (Long Term Evolution) concepts. It discusses the 4G ideal concept, defines LTE and its advantages over 3G technologies. It also describes LTE's technical architecture, types of LTE, network elements, calling procedures, potential business impacts, and future uses. LTE Advanced is introduced as an evolution of LTE to support higher peak data rates of 1Gbps. The document concludes that LTE has surpassed previous generations in mobile communication.
The document discusses:
1) Tips for developing companion specifications for DLMS/COSEM and a case study on using DLMS/COSEM over various communication technologies.
2) An overview of available test tools, including PHENIX, a generic test tool that can be used for testing, conformance, and certification.
3) Andrea's products and services for smart metering, including DLMS/COSEM toolkits, the PEGASUS smart meter, G3-PLC and cellular modules, reading systems, and test and configuration tools.
Content
Brief history about wireless ecosystem.
What is LTE (Long Term Evolution) ?
How is it different from older technologies ?
Network architecture in LTE
Radio Access network (RAN)
Evolved Packet Core (EPC)
Bearers in LTE
Interfaces in LTE
Life Cycle of a UE
LTE RAN overview
Architecture and requirements
Channel bandwidths and operating bands
OFDMA and SC-FDMA
Frequency (LTE-FDD) and time division duplexing (LTE-TDD)
Multiple Antenna techniques in LTE
Channels in LTE and protocol Stack
LTE EPC overview
Architecture
Functions of various elements in EPC
Read other blog posts by the author, Zahid Ghadialy, here: https://communities.cisco.com/people/ZahidGhadialy/content
For more discussions and topics around SP Mobility, please visit our Mobility Community: http://cisco.com/go/mobilitycommunity
Prof. Andy Sutton: 5G RAN Architecture Evolution - Jan 20193G4G
This presentation explores the evolution of GSM, UMTS and LTE radio access network architectures before a detailed review of the RAN architecture options for 5G. The functional decomposition of the 5G radio access network presents the network designer with many challenges with regards placement of RU, DU and CU nodes, all of which are discussed. The presentation concludes with a review of BT UK plans for 5G launch with a fully distributed RAN in support of an EN-DC architecture.
Presented by Professor Andy Sutton CEng FIET, Principal Network Architect, Architecture & Strategy, BT Technology at IET 5G - the Advent conference on 30 January 2019 | IET London: Savoy Place
*** SHARED WITH PERMISSION ***
NB-IoT: a sustainable technology for connecting billions of devicesEricsson
Under the umbrella of 3GPP, radio-access technologies for mobile broadband have evolved effectively to provide connectivity to billions of subscribers and things. Within this ecosystem, the standardization of a radio technology for massive MTC applications – narrowband IoT (NB-IoT) – is also evolving. The aim is for this technology to provide cost-effective connectivity to billions of IoT devices, supporting low power consumption, the use of low-cost devices, and provision of excellent coverage – all rolled out as software on top of existing LTE infrastructure. The design of NB-IoT mimics that of LTE, facilitating radio network evolution and efficient coexistence with MBB, reducing time to market, and reaping the benefits of standardization and economies of scale.
The IoT embeds a broad range of MTC applications, and among the different types, massive MTC – including applications like smart metering, agriculture and real estate monitoring – sets a number of performance targets for connectivity. Attempting to meet these IoT targets using a radio-access technology designed for mobile broadband, however, doesn't make economic sense. Networks that provide connectivity to massive MTC applications need a radio-access technology that can deliver widespread coverage and low power consumption, often in signal-challenged locations. Hence the need for narrowband-IoT (NB-IoT).
NB-IoT is a 3GPP radio-access technology designed to meet the connectivity requirements for massive MTC applications, as well as the design targets for IoT including low device cost, extended coverage, 40 devices per household, long battery life, and uplink latency of under 10 seconds.
NB-IoT enjoys all the benefits of licensed spectrum, the feature richness of EPC, and the overall ecosystem spread of 3GPP. At the same time, NB-IoT has been designed to meet the challenging TCO structure of the IoT market.
This articles reveals how NB-IoT is being designed and how it can be deployed in GSM spectrum, within an LTE carrier, or in an LTE or WCDMA guard band.
3GPP/GSMA technologies for LPWAN in the Licensed SpectrumTiE Bangalore
1) The document discusses 3GPP/GSMA technologies for low-power wide-area networks (LPWAN) in licensed spectrum, including Narrowband IoT (NB-IoT), LTE-M, and EC-GSM.
2) These technologies aim to provide long battery life, low device cost, extended coverage, and support for various traffic patterns including non-IP and IP traffic using techniques like power saving modes and signal repetition.
3) They operate within licensed cellular bands and core network to provide global connectivity, but require a minimum 200kHz spectrum allocation which limits private networks.
Long Term Evolution (LTE) is the next generation of mobile broadband technology that provides higher data rates and network throughput compared to 3G. LTE networks use OFDM and SC-FDMA for downlink and uplink, respectively, along with MIMO and an all-IP architecture to improve performance. The network elements include eNBs, SGWs, PDN GWs and MMEs. For operators, LTE provides an opportunity to increase ARPU through new applications and services while decreasing CCPU through an all-IP infrastructure. Mass deployment of LTE is expected to begin around 2012, with LTE Advanced enabling data rates up to 1 Gbps.
The document discusses Qualcomm Technologies' role in connecting the Internet of Things through cellular technologies like LTE Cat-M1 and NB-IoT. It outlines how these new narrowband LTE technologies optimize cellular to address a wide range of IoT use cases in a low-cost and low-power way while leveraging existing LTE infrastructure. The technologies are designed to deliver benefits like multi-year battery life, ubiquitous coverage including deeper indoor coverage, and support for massive numbers of devices connecting in a heterogeneous connectivity landscape.
5G will be much more than just a new generation with faster peak rates. We are building a unified, more capable 5G platform to connect new industries, enable new services and empower new user experiences. This presentation details the key components for designing the unified, more capable 5G platform featuring an OFDM-based unified air interface. Learn about the key technology enablers for the 5G platform, and see how we are pioneering many of these technologies today with LTE Advanced and Wi-Fi.
For more information on 5G technologies, use cases and timelines, please visit us at www.qualcomm.com/5G.
Examining the Role of SDN and NFV in the Move Towards LTE-A and 5th Generation Alberto Boaventura
This document discusses the roles of SDN and NFV in enabling 5G/LTE-A networks. SDN and NFV can help address challenges of increasing traffic capacity demands through network functions virtualization and software-defined control of network resources. This allows dynamic allocation of resources through network slicing and virtualization. SDN control can also help with interference avoidance through coordination of resources across virtual base stations in a centralized RAN architecture. Overall, SDN and NFV provide mechanisms for elastic, on-demand provisioning of network capacity needed to support the high traffic demands of evolving 5G technologies.
1) 5G shared spectrum technologies pioneered by Qualcomm such as LTE-U, LAA, LWA and MulteFire can unlock unused spectrum and improve spectrum utilization.
2) Qualcomm has contributed significantly to shared spectrum standards like CBRS and is a founder of alliances to develop shared spectrum technologies.
3) 5G New Radio is being designed by Qualcomm to support flexible deployment in shared, licensed, and unlicensed spectrum bands using technologies like LAA and MulteFire.
Rec 12 073 Lte Small Cells Presentation ArrowsAdrian Treacy
Telefonica UK conducted LTE trials in 2009 in Slough, UK to test the performance of LTE technology. The trials aimed to understand coverage, capacity, mobility and user experience on LTE. Key results included achieving peak downlink speeds of 135Mbps and average cell throughput of 25Mbps with LTE, compared to 2-3Mbps on HSPA networks. LTE also showed high mobility performance with over 99.9% success between LTE cells and low interruption times. The trials provided learning for Telefonica on LTE network planning, deployment and optimization.
Propelling 5G forward: a closer look at 3GPP Release-16Qualcomm Research
This presentation summarizes the 3GPP 5G NR Release 16 projects, including eMBB enhancements, unlicensed, sidelink, IAB, TSN, eURLLC, private networks, C-V2X, and more...
Qualcomm Technologies presented potential 5G use cases and characteristics. 5G is targeting a range of services including enhanced mobile broadband, wide area IoT, high reliability, and smart cities. It will utilize improved RF capabilities, virtualized network elements, and new air interface designs using new spectrum such as mmWave bands and massive MIMO. 5G aims to deliver improved user experience, coverage, cost efficiency, and new services across diverse topologies and cell sizes through a unified design approach across spectrum types and bands.
5g technology is a unique combination of high speed internet access , low latency , high reliability & seamless coverage which will support no. of vehicles & transport infrastructure. 5G platform will impact many industries like automotive , entertainment, agriculture , manufacturing and IT. As per the research forecast “IOT will account for one quarter of the global 41 million 5G connections in 2024”, out of these ¾ of the devices will be auto industry via embedded vehicle connections.
There are wide range of applications that will benefit from 5G ultra fast networks and real time responsiveness of the network.These properties of 5G technology are very important for many applications of IOT e.g self driven cars , intelligent transportation which demands very low latency .This will be a great boom for interactive mobile gaming which is bandwidth hungry application. 5G technology enables us to control more devices remotely in various applications where real time network performance is critical, like remote control of vehicles. It focuses on worker safety as well as monitoring environment. 5G technology is not focusing on improving speed , but this will prove best in evolution of business etc. IOT in 5G have excelled in connecting number of phones , tablets and other devices, however connecting cars , meters, sensors require more advanced business models.
Migration to 5G and Deployment Training and certification by TELCOMA GlobalGaganpreet Singh Walia
5G technology enables enhanced mobile broadband services, which offers higher data rates, lower latency and more capacity. Development of 5G technology is being led by companies such as Huawei, Intel and Qualcomm for modem technology. Lenovo, Nokia, Ericsson, ZTE, Cisco and Samsung is working on infrastructure.
For deployment of 5G, 3GPP is defining new core network as well as new radio access network. New core network of 5G is 5GC and new radio access technology called “5G NR” new radio.5G use cases are already being built around immersive sports viewing and augmented reality applications.
The document provides an overview of 5G technology. It discusses how 5G networks will be able to handle 10,000 times more call and data traffic than 4G and have data download speeds several hundred times faster than 4G. It also outlines the evolution from 1G to 5G mobile networks and compares key features. The architecture of 5G is explained, including the radio access network and 5G nanocore. Functional aspects like quality of service classes and reference points are also summarized.
This document discusses the intersection of 5G networks and open reference platforms. Open reference platforms using disaggregated RAN architectures and open interfaces can offer new user experiences through edge computing and adaptive analytics. Challenges include developing principles for graph abstraction of radio networks and understanding service layers and multi-tenancy in open and democratized architectures. Open source communities and standards bodies are collaborating on initiatives like O-RAN and ONAP to define open interfaces and platforms that enable a more programmable radio access network.
AT&T View on LTE to 5G Network Migration Eiko Seidel
AT&T proposes a three step approach to evolving 5G architecture from early deployment to more mature phases:
1) Early 5G deployment using Phase 1 Option 3 architecture.
2) Phase 1 evolution to Option 7 architecture while still supporting Option 3, through software upgrades.
3) Phase 2 evolution to Option 2/4 architecture while still supporting Options 3 and 7, with specifications that allow different architectures to coexist.
This document provides an overview of LTE (Long Term Evolution) concepts. It discusses the 4G ideal concept, defines LTE and its advantages over 3G technologies. It also describes LTE's technical architecture, types of LTE, network elements, calling procedures, potential business impacts, and future uses. LTE Advanced is introduced as an evolution of LTE to support higher peak data rates of 1Gbps. The document concludes that LTE has surpassed previous generations in mobile communication.
The document discusses:
1) Tips for developing companion specifications for DLMS/COSEM and a case study on using DLMS/COSEM over various communication technologies.
2) An overview of available test tools, including PHENIX, a generic test tool that can be used for testing, conformance, and certification.
3) Andrea's products and services for smart metering, including DLMS/COSEM toolkits, the PEGASUS smart meter, G3-PLC and cellular modules, reading systems, and test and configuration tools.
Neeraj Goyal has over 5 years of experience in the telecom industry testing 4G/3G wireless networks and protocols. He has expertise testing virtualized mobile core functions and network elements like MME, SGSN, SGW/PGW. He is proficient with interfaces like S6, GX, S5/S8, S1AP, S4, Gb/Iu, Gn and protocols like GTPv2 and Diameter. Currently based in Bangalore, India, he is looking for opportunities to utilize his experience with virtualization, LTE networks, protocol conformance testing and tool expertise.
Transition from PROFIBUS to PROFINET Network | WebinarSadatulla Zishan
This document discusses transitioning from a PROFIBUS to a PROFINET network. It provides an overview of PROFINET, the differences between PROFIBUS and PROFINET networks, planning considerations for PROFINET networks including parameters like netload and line depth, quality measurement techniques, and tips for diagnosing issues. It also presents a case study where diagnostic tools from Indu-Sol helped resolve intermittent communication issues on a PROFINET network.
Haiping (Tom) He has over 10 years of experience in analog and digital circuit design for wireless telecommunications products. He has worked as a senior test engineer and hardware technician supervisor testing avionics equipment. Currently, he is looking for a new opportunity utilizing his strong background in circuit design, embedded systems, and testing across various industries.
- Mohd Javaid Khan has over 7 years of experience testing wireless protocols like LTE, UMTS, WCDMA, GSM, and GPRS for companies like Mediatek, Analog Devices, Motorola, Alcatel-Lucent, Infineon, Apple, Intel Mobile Communication, and T-Mobile UK.
- He currently works as a Satellite Technical Leader based in Delhi, India managing protocol testing teams in Asia Pacific.
- His responsibilities include test planning, case design, issue tracking, and ensuring quality of field testing.
COMPLETED CV IN ENGLISH.
ANY PROBLEMS, PLEASE CONTACT ME DIRECT BY EMAIL OR TELEPHONE
ALEXANDRE GUIDA --> guida.alexandre@hotmail.com
tel.: 55-21-98848-4245 (I use whatsup!)
- Meganathan B has over 7 years of experience in testing automotive infotainment systems and rear radar systems. He has experience in system, unit, and real-time testing using various tools like Vector Canoe, Doors, Citrix, SiTemppo, JIRA, TTFis, and VectorCAST.
- He has worked on projects for customers like JLR, Volvo, Ford, GM, and others. His responsibilities included test case development, requirement-based testing, unit testing, and bug reporting.
- He holds a B.E. in Electronics and Communication Engineering and has knowledge of C programming and CAPL scripting.
Design and Experiment Platform for Industrial Wireless SystemsRyan
Cite This Work: Peng Hu. "Design and Experiment Platform for Industrial Wireless Systems", The 10th Annual UNENE I&C Workshop, Toronto, Canada, Oct. 24th, 2014.
This presentation introduces an experiment platform for industrial wireless systems done by CMC in collaboration with Western University.
ANGELA is an HTTP adaptive streaming and edge computing simulator that was developed to address limitations of other simulators. It focuses on video streaming and edge computing mechanisms. ANGELA imports real radio traces or data from NS-3 for accurate wireless simulations and reduces simulation time. It also simulates various adaptive bitrate algorithms located at the client, edge, or server. ANGELA provides metrics to evaluate streaming quality and supports custom video datasets and machine learning techniques. The developers hope to publicly release ANGELA to evaluate new adaptive streaming and edge computing approaches.
Tony Yuhong has over 15 years of experience in the telecommunications industry focusing on optical transmission networks. He has worked for Alcatel-Lucent, Tellabs, and Coriant in roles such as new product introduction specialist, technical support specialist, and project implementation supervisor. Tony has extensive knowledge of SDH, WDM, OTN, and other optical networking technologies and protocols. He is skilled at system testing, troubleshooting, customer training, and technical support.
Prateek Gupta is seeking a position as an Embedded Engineer with experience in embedded software and hardware development. He has over 7 years of experience in roles such as Embedded Firmware Engineer and Senior Embedded Design Engineer. Some of his key skills and responsibilities include embedded system design, development, debugging and testing using languages like C and microcontrollers like ARM, AVR and PIC. He has expertise in areas such as requirements specification, product development, client interaction and technical support.
In business most questions must satisfy a commercial rationale. Any monetary investment
needs to have justification with a confidently predicted return on that investment. So what
improvements can be reasonably expected from the decision to migrate? In this report, we consider a few of the more frequently undertaken migration projects:
1) Analogue control equipment to digital control equipment.
2) Obsolete PLC to Current PLC
3) DC motor control technology to AC technology
4) Traditional copper cable machine wiring and distributed Fieldbus networks.
Lalatendu Pothal is seeking a position as a Telecom Engineer with 5 years of experience in telecom testing. He has experience testing LTE, WCDMA, HSPA+, GSM technologies using tools like Agilent, Anritsu, BOA, Panda, Wildcat, Anite and Spirent. His experience includes LTE and WCDMA performance testing, functional testing, stability testing, and protocol testing. He is proficient in Python, Perl, and basic C and has expertise in Qualcomm and Mediatek chipsets.
This document discusses the evolution of 5G technology. It provides an overview of previous generations of wireless communication technology (1G-4G) and their key features. 5G is presented as the next major phase, promising speeds up to 20 Gbps, greatly increased bandwidth and connection capacity. The document outlines some of 5G's expected capabilities and technical requirements. It also explores the potential impacts and applications of 5G technology, such as enabling further advances in industries and providing more efficient services through technologies like IoT.
This document provides a summary of Mallikarjuna Rathod's professional experience as a Project Lead for HP Enterprise services. Some key points:
- He has over 8 years of experience in the IT industry and 6 years experience in telecom testing.
- He is responsible for ensuring quality of testing activities, assigning testers to projects, test planning and monitoring, and preparing for and attending daily meetings.
- He has experience managing multiple projects for Belgacom/Proximus, including testing various telecom systems and applications.
- His technical skills include databases, testing tools like QCT and ALM, and programming languages like UNIX.
Multi-access Edge Computing (MEC) provides cloud computing capabilities and an IT service environment at the edge of the network. This reduces latency and allows for real-time applications and analytics. MEC extends cloud capabilities to places where people and devices connect to mobile networks. Some key benefits of MEC include improved user experience, network-based service innovation, and new applications for subscribers, enterprises and vertical industries. Examples of potential MEC applications discussed in the document include video acceleration, augmented reality, connected vehicles, IoT analytics, and more.
Nikhil Muraleedharan has over 4 years of experience in telecommunication software testing and integration focusing on 4G/3G technologies. He has worked on various projects involving the testing, integration and development of LTE protocol stacks and core network elements. His skills include expertise in LTE/UMTS protocols, tools like Aeroflex and Wireshark, programming in C, and experience across the full product development lifecycle from requirements to integration testing.
Engineer Sensors For Digital Transformation Webinar PPTSadatulla Zishan
Do you want to know the current Industrial sensor demands? Are you facing challenges in identifying the right #Industrial protocol? Want to know how to interface the #sensors with different industrial protocols?
Don't worry, we have answered these questions in a focused webinar on #sensorengineering titled “Engineer Sensors for Digital Transformation” on 9th June 2021 2021 at 12 PM EST (USA, Canada Time).
Our expert panelist Mr. Sarang P, Embedded Design Expert joined with Mr. Namdev Nayak, Embedded Design Specialist guided the attendees on the industrial sensors and trending communication protocols in field devices.
In the 60 minutes of the #webinar, they covered:
1. Overview of the industrial sensors and #communicationprotocols
2. How to choose the right communication protocol & sensor when designing
3. Architecture and implementation of #industrialsensor & its various components
4. How is AI implemented in sensor modules
You can view the webinar recording by clicking on the link https://youtu.be/zpknpt4_uhQ
Please feel free to share these links with your colleagues who may be interested.
If you have any queries or require more information regarding the topic or wish to know more about Utthunga you can mail us at contact@utthunga.com or visit our website https://utthunga.com/
This individual has over 23 years of experience in hardware/RF design engineering, including experience in automotive camera and video processing systems. They are seeking a challenging position in hardware/RF R&D in the automotive or consumer electronics industries utilizing their experience in bringing ideas from concept to production, including prototyping, testing, and manufacturing.
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