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All-IP packet switched network. Da
All-IP packet switched network.
Data rates up to 100 Mbps for high mobility and up to 1 Gbps for low mobility.
Seamless connectivity and global roaming
Interoperability with existing wireless standards
Smooth handovers.
High QoS.
There are a number of standards and technologies pertaining to each wireless generation -- GSM, cdmaOne, GPRS, EDGE, CDMA2000, UMTS (also marketed as 3GSM), HSDPA, among others. For practical reasons, we won't be dwelling on the technicalities of each term and instead will move onto the ones that involve our topic of interest here: 4G. Although no set of standards have been established as of yet by the International Telecommunication Union (ITU), the authority on such things, two competing technologies have been proposed: LTE and WiMAX. Many service providers often use the term 4G mobile broadband to describe the technologies they are offering based on their own, sometimes distorted definitions. However, current implementations are largely considered pre-4G, as they don't fully comply with the planned requirements of 1Gbit/s for stationary reception and 100Mbit/s for mobile. Besides speed, several other guidelines have been traced for wireless communication standards to qualify as 4G. In a nutshell, and utilize the network resources to support more simultaneous users per cell, have smooth handovers across heterogeneous networks, offer high quality of service for next generation multimedia support, and should be based on an all-IP packet switched network.
Project Report on 4G Wireless 13
3.1.1 Long-Term Evolution-(LTE):
Short for Long-Term Evolution, LTE is considered by many to be the natural successor to current-generation 3G technologies, in part because it updates UMTS networks to provide significantly faster data rates for both uploading and downloading. The specification calls for downlink peak rates of at least 100Mb/s and an uplink of 50Mb/s, but going by real world tests its transfer speeds will more likely range from 5-12Mb/s for downloads and 2-5Mb/s for uploads. LTE is being developed by a group of telecommunications associations known as the 3rd Generation Partnership Project, or 3GPP, as an eight release of what has been evolving since 1992 from the GSM family of standards. There are two fundamental aspects of LTE. The first is that the technology finally leaves behind the circuit switched network of its GSM roots and moves to an all-IP flat networking architecture. This is a significant shift which in very simple terms means that LTE will treat everything it transmits, even voice, as data. The other big change relates to the use of MIMO technology, or multiple antennas at both the transmitter and receiver end to improve communication performance. This setup can either be used to increase the throughput data rates or to reduce interference. Many big-name global operators and mobile communications companies are backing LTE in the race for 4G mobile broadband, including Vodafone, Orange, T-Mobile, LG Electronics, Ericsson, Nokia, Siemens, NTT DoMoCo, and others. In the U.S., Verizon Wireless has said it is going commercial with its LTE network in the fourth quarter, with 25 to 30 markets up and ready at launch. AT&T and T-Mobile claim they will begin to deploy LTE in 2011, but in the meantime both networks have moved to HSPA 7.2 and the latter plans to roll out HSPA+ beginning this year. Theoretically these can support speeds of up to 7.2 and 21 Mbps, respectively, but in real world scenarios they are only marginally faster than most 3G data services.
The reason behind LTE‟s strong industry s
upport lies in the relative ease of upgrading from current 3G networks worldwide over to LTE
Project Report on 4G Wireless 14
mobile broadband, compared to the significant infrastructure build out that WiMAX has taken thus far. Fewer cell sites have to be built and penetration into buildings is better at the 700 MHz spectrum LTE uses. However, WiMAX deployments are already up and running while LTE's formal debut is still a few months out
Data rates up to 100 Mbps for high mobility and up to 1 Gbps for low mobility.
Seamless connectivity and global roaming
Interoperability with existing wireless standards
Smooth handovers.
High QoS.
There are a number of standards and technologies pertaining to each wireless generation -- GSM, cdmaOne, GPRS, EDGE, CDMA2000, UMTS (also marketed as 3GSM), HSDPA, among others. For practical reasons, we won't be dwelling on the technicalities of each term and instead will move onto the ones that involve our topic of interest here: 4G. Although no set of standards have been established as of yet by the International Telecommunication Union (ITU), the authority on such things, two competing technologies have been proposed: LTE and WiMAX. Many service providers often use the term 4G mobile broadband to describe the technologies they are offering based on their own, sometimes distorted definitions. However, current implementations are largely considered pre-4G, as they don't fully comply with the planned requirements of 1Gbit/s for stationary reception and 100Mbit/s for mobile. Besides speed, several other guidelines have been traced for wireless communication standards to qualify as 4G. In a nutshell, and utilize the network resources to support more simultaneous users per cell, have smooth handovers across heterogeneous networks, offer high quality of service for next generation multimedia support, and should be based on an all-IP packet switched network.
Project Report on 4G Wireless 13
3.1.1 Long-Term Evolution-(LTE):
Short for Long-Term Evolution, LTE is considered by many to be the natural successor to current-generation 3G technologies, in part because it updates UMTS networks to provide significantly faster data rates for both uploading and downloading. The specification calls for downlink peak rates of at least 100Mb/s and an uplink of 50Mb/s, but going by real world tests its transfer speeds will more likely range from 5-12Mb/s for downloads and 2-5Mb/s for uploads. LTE is being developed by a group of telecommunications associations known as the 3rd Generation Partnership Project, or 3GPP, as an eight release of what has been evolving since 1992 from the GSM family of standards. There are two fundamental aspects of LTE. The first is that the technology finally leaves behind the circuit switched network of its GSM roots and moves to an all-IP flat networking architecture. This is a significant shift which in very simple terms means that LTE will treat everything it transmits, even voice, as data. The other big change relates to the use of MIMO technology, or multiple antennas at both the transmitter and receiver end to improve communication performance. This setup can either be used to increase the throughput data rates or to reduce interference. Many big-name global operators and mobile communications companies are backing LTE in the race for 4G mobile broadband, including Vodafone, Orange, T-Mobile, LG Electronics, Ericsson, Nokia, Siemens, NTT DoMoCo, and others. In the U.S., Verizon Wireless has said it is going commercial with its LTE network in the fourth quarter, with 25 to 30 markets up and ready at launch. AT&T and T-Mobile claim they will begin to deploy LTE in 2011, but in the meantime both networks have moved to HSPA 7.2 and the latter plans to roll out HSPA+ beginning this year. Theoretically these can support speeds of up to 7.2 and 21 Mbps, respectively, but in real world scenarios they are only marginally faster than most 3G data services.
The reason behind LTE‟s strong industry s
upport lies in the relative ease of upgrading from current 3G networks worldwide over to LTE
Project Report on 4G Wireless 14
mobile broadband, compared to the significant infrastructure build out that WiMAX has taken thus far. Fewer cell sites have to be built and penetration into buildings is better at the 700 MHz spectrum LTE uses. However, WiMAX deployments are already up and running while LTE's formal debut is still a few months out
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Chuyển sang mạng toàn-IP gói tin. Dữ liệu tỷ lệ lên đến 100 Mbps cho tính di động cao và lên đến 1 Gbps cho di động thấp. Khả năng kết nối liền mạch và chuyển vùng toàn cầu Tương thích với tiêu chuẩn không dây hiện có Mịn handovers. QoS cao.Một số tiêu chuẩn và các công nghệ liên quan đến mỗi thế hệ không dây - GSM, cdmaOne, GPRS, EDGE, CDMA2000, UMTS (cũng được quảng bá 3GSM), HSDPA, trong số những người khác. Vì lý do thực tế, chúng tôi sẽ không ở trên technicalities của mỗi nhiệm kỳ và thay vào đó sẽ di chuyển lên những người có liên quan đến chủ đề của chúng tôi quan tâm ở đây: 4G. Mặc dù không có thiết lập các tiêu chuẩn đã được thành lập như là của được nêu ra bởi các International Telecommunication Union (ITU), thẩm quyền về những điều đó, hai công nghệ này cạnh tranh đã được đề xuất: LTE và WiMAX. Cung cấp nhiều dịch vụ thường sử dụng các thuật ngữ 4G điện thoại di động băng thông rộng để mô tả các công nghệ họ đang cung cấp dựa trên định nghĩa của riêng mình, đôi khi bị bóp méo. Tuy nhiên, hiện nay triển khai chủ yếu được coi là pre - 4G, vì họ không hoàn toàn tuân thủ các yêu cầu quy hoạch của 1Gbit/s cho Lễ tân văn phòng phẩm và 100Mbit/s cho điện thoại di động. Bên cạnh đó tốc độ, một số các hướng dẫn khác đã được phát cho giao tiếp không dây tiêu chuẩn để đủ điều kiện như 4G. Tóm lại, sử dụng tài nguyên mạng để hỗ trợ nhiều người dùng hơn đồng thời mỗi tế bào, có mịn handovers qua mạng không đồng nhất, cung cấp chất lượng cao của các dịch vụ tiếp theo thế hệ hỗ trợ đa phương tiện và phải được dựa trên một gói chuyển sang mạng toàn-IP. Dự án báo cáo về 4G Wireless 133.1.1 Evolution-(LTE) dài hạn:Short for Long-Term Evolution, LTE is considered by many to be the natural successor to current-generation 3G technologies, in part because it updates UMTS networks to provide significantly faster data rates for both uploading and downloading. The specification calls for downlink peak rates of at least 100Mb/s and an uplink of 50Mb/s, but going by real world tests its transfer speeds will more likely range from 5-12Mb/s for downloads and 2-5Mb/s for uploads. LTE is being developed by a group of telecommunications associations known as the 3rd Generation Partnership Project, or 3GPP, as an eight release of what has been evolving since 1992 from the GSM family of standards. There are two fundamental aspects of LTE. The first is that the technology finally leaves behind the circuit switched network of its GSM roots and moves to an all-IP flat networking architecture. This is a significant shift which in very simple terms means that LTE will treat everything it transmits, even voice, as data. The other big change relates to the use of MIMO technology, or multiple antennas at both the transmitter and receiver end to improve communication performance. This setup can either be used to increase the throughput data rates or to reduce interference. Many big-name global operators and mobile communications companies are backing LTE in the race for 4G mobile broadband, including Vodafone, Orange, T-Mobile, LG Electronics, Ericsson, Nokia, Siemens, NTT DoMoCo, and others. In the U.S., Verizon Wireless has said it is going commercial with its LTE network in the fourth quarter, with 25 to 30 markets up and ready at launch. AT&T and T-Mobile claim they will begin to deploy LTE in 2011, but in the meantime both networks have moved to HSPA 7.2 and the latter plans to roll out HSPA+ beginning this year. Theoretically these can support speeds of up to 7.2 and 21 Mbps, respectively, but in real world scenarios they are only marginally faster than most 3G data services.Lý do đằng sau LTE‟s ngành công nghiệp mạnh mẽ support nằm trong tương đối dễ dàng nâng cấp từ mạng 3G hiện nay trên toàn thế giới qua LTE Dự án báo cáo về 4G Wireless 14điện thoại di động băng thông rộng nhất, so với xây dựng cơ sở hạ tầng quan trọng ra rằng WiMAX đã vậy, đến nay. Ít di động các trang web đã được xây dựng và thâm nhập vào các tòa nhà tốt hơn lúc phổ 700 MHz LTE sử dụng. Tuy nhiên, triển khai WiMAX đang hoạt động và chạy trong khi của LTE chính thức ra mắt vẫn còn một vài tháng trong
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