This document is a seminar report on femtocell technology submitted by a student named Hareesh P. It provides an introduction to femtocells, defining them as low-power wireless access points that use a home broadband connection to connect mobile devices to a mobile network operator's network. It discusses the need for femtocells to improve indoor coverage and capacity as more users access mobile networks at home. The document also classifies femtocells based on their bearer connection and initial access information capabilities. It provides a basic overview of how femtocells function by connecting to the operator's core network via broadband and operating at low power for indoor coverage while handing off to the macro network outdoors.
Femtocells, a technology little-known outside the wireless world, promise better indoor cellular service. In telecommunication, a Femtocell is a small cellular base station, typically designed for use in a home or small business. It connects to the service provider’s network via broadband.
Current designs typically support 2 to 4 active mobile phones in a residential setting, and 8 to 16 active mobile phones in enterprise settings. A Femtocell allows service providers to extend service coverage indoors, especially where access would otherwise be limited or unavailable. For a mobile operator, the attractions of a Femtocell are improvements to both coverage and capacity, especially indoors. A Femtocell is typically the size of a residential gateway or smaller, and
connects into the end-user’s broadband line. Once plugged in, the Femtocell connects to the MNO’s mobile network, and provides extra coverage in a range of typically 30 to 50 meters for residential Femtocells. The end-user must declare which mobile phone numbers are allowed to connect to his/her Femtocell, usually via a web interface provided by the MNO. When these mobile phones arrive under coverage of the Femtocell, they switch over from the Macrocell (outdoor) to the
Femtocell automatically. All communications will then automatically go through the Femtocell.
This document provides an overview of femtocell technology. It defines a femtocell as a small cellular base station for use in homes and small businesses that connects to the mobile network via broadband. The document describes the need for femtocells to improve indoor coverage, their advantages like increased capacity and coverage, different types (2G, 3G, OFDM), key elements of the femtocell network architecture, and how femtocells work by connecting to the internet to route calls and data. It also covers femtocell characteristics and the future potential of the technology.
Femtocell technology provides improved cellular coverage and network capacity. It involves placing small, low-power cellular base stations called femtocells inside homes and offices connected to the internet via broadband. This allows indoor users to connect to the cellular network and offloads traffic from macrocell towers. Femtocells operate at very low power levels within a range of around 200 meters and connect back to the cellular provider's network via an existing broadband internet connection. They provide benefits such as improved coverage, network capacity, and reduced subscriber turnover for cellular providers.
The document discusses femtocells, which are small cellular base stations that provide indoor wireless coverage to mobile phones using a broadband internet connection. Femtocells allow service providers to extend cellular coverage inside homes and businesses. They provide benefits to both users and operators, including improved coverage, higher quality and data rates, lower costs, increased network capacity, and better performance. The document outlines what femtocells are, how they work, their benefits, advantages, applications, and concludes that femtocell technology represents an important improvement for future networks.
Femtocells are small cellular base stations that connect to service providers' networks via broadband to extend indoor cellular coverage. They allow service in homes and businesses where access would otherwise be limited. Femtocells operate in plug-and-play mode but require dedicated hardware. They connect via IPsec tunnels to security gateways and authenticate users for secure cellular service extension into private locations. Femtocells help improve indoor coverage while potentially lowering call costs.
The document discusses femtocell technology, which uses small, low-power cellular base stations installed in homes or offices to improve indoor mobile coverage and network capacity. Femtocells connect to a mobile provider's network via broadband and support 2-5 mobile devices. They enhance coverage in areas where signals from larger macrocell towers are weak indoors. This allows providers to extend service coverage while reducing infrastructure costs and improving customer experience through better signal quality inside buildings.
Seminar presentation On Femtocell Technologyjit1994roy
Femtocell technology provides improved cellular coverage for indoor spaces. A femtocell is a small cellular base station that connects to a service provider's network via broadband to improve coverage for mobile phones within a home or business. Femtocells can support a few mobile phones within a range of 10-50 meters and help alleviate capacity constraints on the macro network by shifting traffic indoors. They provide benefits like improved coverage, capacity, and battery life for users along with increased revenue and customer satisfaction for providers. However femtocells require a broadband connection and don't support outdoor coverage. Future research aims to develop femtocells that can support 4G/5G networks and integrate with other home devices.
This document discusses femtocells, which are small, low-power cellular base stations that improve indoor wireless coverage and capacity. It outlines problems with existing mobile technologies like low indoor signal strength. Femtocells have a range of 10-50 meters, are installed in homes, and connect to a broadband internet connection. The document describes femtocell components, architecture, benefits for cellular users and networks in terms of improved coverage, capacity and offloading data traffic. It also covers technical and economic challenges and concludes that femtocells can alleviate pressure on macrocell networks and help accelerate existing mobile technologies.
Femtocells, a technology little-known outside the wireless world, promise better indoor cellular service. In telecommunication, a Femtocell is a small cellular base station, typically designed for use in a home or small business. It connects to the service provider’s network via broadband.
Current designs typically support 2 to 4 active mobile phones in a residential setting, and 8 to 16 active mobile phones in enterprise settings. A Femtocell allows service providers to extend service coverage indoors, especially where access would otherwise be limited or unavailable. For a mobile operator, the attractions of a Femtocell are improvements to both coverage and capacity, especially indoors. A Femtocell is typically the size of a residential gateway or smaller, and
connects into the end-user’s broadband line. Once plugged in, the Femtocell connects to the MNO’s mobile network, and provides extra coverage in a range of typically 30 to 50 meters for residential Femtocells. The end-user must declare which mobile phone numbers are allowed to connect to his/her Femtocell, usually via a web interface provided by the MNO. When these mobile phones arrive under coverage of the Femtocell, they switch over from the Macrocell (outdoor) to the
Femtocell automatically. All communications will then automatically go through the Femtocell.
This document provides an overview of femtocell technology. It defines a femtocell as a small cellular base station for use in homes and small businesses that connects to the mobile network via broadband. The document describes the need for femtocells to improve indoor coverage, their advantages like increased capacity and coverage, different types (2G, 3G, OFDM), key elements of the femtocell network architecture, and how femtocells work by connecting to the internet to route calls and data. It also covers femtocell characteristics and the future potential of the technology.
Femtocell technology provides improved cellular coverage and network capacity. It involves placing small, low-power cellular base stations called femtocells inside homes and offices connected to the internet via broadband. This allows indoor users to connect to the cellular network and offloads traffic from macrocell towers. Femtocells operate at very low power levels within a range of around 200 meters and connect back to the cellular provider's network via an existing broadband internet connection. They provide benefits such as improved coverage, network capacity, and reduced subscriber turnover for cellular providers.
The document discusses femtocells, which are small cellular base stations that provide indoor wireless coverage to mobile phones using a broadband internet connection. Femtocells allow service providers to extend cellular coverage inside homes and businesses. They provide benefits to both users and operators, including improved coverage, higher quality and data rates, lower costs, increased network capacity, and better performance. The document outlines what femtocells are, how they work, their benefits, advantages, applications, and concludes that femtocell technology represents an important improvement for future networks.
Femtocells are small cellular base stations that connect to service providers' networks via broadband to extend indoor cellular coverage. They allow service in homes and businesses where access would otherwise be limited. Femtocells operate in plug-and-play mode but require dedicated hardware. They connect via IPsec tunnels to security gateways and authenticate users for secure cellular service extension into private locations. Femtocells help improve indoor coverage while potentially lowering call costs.
The document discusses femtocell technology, which uses small, low-power cellular base stations installed in homes or offices to improve indoor mobile coverage and network capacity. Femtocells connect to a mobile provider's network via broadband and support 2-5 mobile devices. They enhance coverage in areas where signals from larger macrocell towers are weak indoors. This allows providers to extend service coverage while reducing infrastructure costs and improving customer experience through better signal quality inside buildings.
Seminar presentation On Femtocell Technologyjit1994roy
Femtocell technology provides improved cellular coverage for indoor spaces. A femtocell is a small cellular base station that connects to a service provider's network via broadband to improve coverage for mobile phones within a home or business. Femtocells can support a few mobile phones within a range of 10-50 meters and help alleviate capacity constraints on the macro network by shifting traffic indoors. They provide benefits like improved coverage, capacity, and battery life for users along with increased revenue and customer satisfaction for providers. However femtocells require a broadband connection and don't support outdoor coverage. Future research aims to develop femtocells that can support 4G/5G networks and integrate with other home devices.
This document discusses femtocells, which are small, low-power cellular base stations that improve indoor wireless coverage and capacity. It outlines problems with existing mobile technologies like low indoor signal strength. Femtocells have a range of 10-50 meters, are installed in homes, and connect to a broadband internet connection. The document describes femtocell components, architecture, benefits for cellular users and networks in terms of improved coverage, capacity and offloading data traffic. It also covers technical and economic challenges and concludes that femtocells can alleviate pressure on macrocell networks and help accelerate existing mobile technologies.
(1) BSNL provides various telecommunication services across India including landline, cellular, broadband, and enterprise solutions. (2) A telecommunication network consists of exchanges, distribution frames, and switch rooms to connect subscribers and route calls. (3) BSNL offers different internet technologies like leased lines, WiFi, GPRS, and broadband to provide high-speed connectivity to users.
Wi-Fi is a wireless technology that allows devices to connect to the internet and each other without wires. It uses radio waves to transmit and receive data over short distances. The main components of a Wi-Fi network are access points, Wi-Fi cards in devices, and security measures. Wi-Fi provides mobility, ease of installation, and flexibility but has limitations like interference, performance degradation, high power usage, and limited range. It has many applications beyond basic internet access like streaming, file sharing, and smart home device synchronization.
Femtocell is a small, low-power cellular base station designed for use in homes or small businesses. It connects standard mobile devices to a mobile operator's network using a residential broadband connection, extending cellular coverage indoors where it may otherwise be limited or unavailable. Femtocells improve coverage and network capacity while reducing costs for both end users and mobile operators. Security risks associated with femtocells include threats to user privacy, denial of service attacks, and potential for fraud but these can be mitigated through security measures like IPsec and authentication protocols.
Femtocells are small cellular base stations that operate in a licensed spectrum to improve indoor wireless coverage. They connect to the mobile network via a user's home internet connection. Femtocells offer benefits like improved voice and data quality for users and increased network capacity for operators by offloading traffic. However, challenges remain around interference management, mobility, and regulatory issues regarding spectrum usage. As femtocell technology evolves, it has the potential to provide widespread indoor coverage and high data rates to meet future network demands.
This document provides a detailed study on femtocells. It begins with an introduction that defines a femtocell as a small cellular base station for use in homes or small businesses that connects to a service provider's network via broadband. The history section then discusses the early development of femtocell technology from 2002-2007. It proceeds to explain how femtocells work and their technical benefits for both users and operators, such as improved indoor coverage, reduced costs, and increased network capacity and coverage. The document defines femtocells and differentiates them from picocells and WiFi. It also outlines femtocell features, user benefits, and operator benefits. In conclusion, it discusses how femtocells extend high-data rate
Wireless networking in schools provides mobility for students and supports e-learning. It allows students to access the curriculum and research resources from anywhere in the school using devices like laptops and tablets. Wireless networks eliminate the need to run cables and wires, making installation faster and more flexible. They also reduce costs compared to wired networks. While wireless improves access and mobility, schools must also implement security measures to protect their network and devices on it. Newer wireless standards like 802.11ac provide faster speeds and greater capabilities to meet the needs of students' use of technology in schools.
LTE-A HetNets using Carrier Aggregation - Eiko Seidel, CTO, Nomor ResearchEiko Seidel
LTE-Advanced standardisation in Release 10 was completed in early 2011 and commercial network deployments using first Release 10 features are likely to be announced later this year. One of the most attractive features of LTE-A is Carrier Aggregation, where a user equipment (UE) might be scheduled across multiple carriers. Besides this, Heterogeneous Networks (HetNet) using small cells gained a lot of interest recently due to their potential to increase network capacity. This white paper provides some insight into how LTE-A HetNets with or without a centralized architecture might be deployed today and in the future, in particular in combination with Carrier Aggregation.
Seminar Presentation on Femtocell Technology
A femtocell is a small device that is used to improve
wireless coverage over a small area, mostly indoor. It is a small cellular base station, also
called a wireless access point that connects to a broadband Internet connection and broadcasts
it into radio waves in its area of coverage.
This document provides an overview of Wi-Fi technology, including its standards, network elements, configurations, applications, security threats and advantages/disadvantages. It discusses the IEEE 802.11b, 802.11a and 802.11g wireless standards and how they operate at different speeds and frequencies. It describes the basic components of a Wi-Fi network including access points and Wi-Fi cards. It also summarizes different Wi-Fi network topologies and security threats like eavesdropping, man-in-the-middle attacks and denial-of-service.
This 3 sentence summary provides the high level information about the document:
The document discusses Bharat Sanchar Nigam Limited (BSNL), India's state-owned telecommunications company. It covers the basic workings of a telecommunications network, components of BSNL exchanges like the main distribution frame, and mobile communication technologies used by BSNL like GSM, GPRS, CDMA. The document also discusses internet services provided by BSNL including broadband, WiMAX, FTTH and provides an overview of optical fiber transmission systems.
Bharat Sanchar Nigam Limited (BSNL) is India's largest telecommunications company that provides various telecom services across India. It operates through telephone exchanges that house switching equipment to facilitate call connections. The exchanges have different components like the main distribution frame for fault removal, power plants for electricity supply, and switch rooms containing cabinets for routing calls. BSNL also offers broadband internet through technologies like ADSL that provide high-speed connectivity to customers via the existing telephone network infrastructure.
Pankaj KR Purbey underwent a 14-day vocational training in basic telecommunications at RTTC BSNL in Guwahati. The document provides an overview of BSNL services and telecommunication networks in India. It discusses the architecture of telecom networks including user equipment, access networks, switching networks, and transmission networks. It also describes the key networks operated by BSNL including landline, mobile, WLL, internet/broadband, ISDN, and data networks. The document further explains concepts of multiplexing including FDM, WDM, and TDM. It provides details of pulse code modulation techniques involving filtering, sampling, quantization, encoding, and multi-frame structures
5G/NR wireless communication technology overview, architecture and its operating modes SA and NSA. Also an introduction to VoNR and other services overview of 5G network.
The key technologies of 5G namely MIMO and Network slicing are also explained.
Femtocell technology provides improved indoor mobile phone coverage and capacity. A femtocell is a small cellular base station that connects standard mobile devices to a mobile operator's network using a residential broadband connection. Femtocells enhance signal quality and coverage for mobile users inside homes and offices by establishing a mini cellular network connected to the macro network of the mobile operator. They offer benefits like improved coverage, increased network capacity, and a better user experience for calls made indoors.
This document discusses WiMAX (Worldwide Interoperability for Microwave Access), a wireless technology that provides broadband connections over long distances. It operates using towers and receivers. WiMAX works by transmitting signals from towers that can cover large areas, up to 50 km. Receivers pick up the signal and can be internal cards or external boxes. The document outlines key features of WiMAX including scalability to support thousands of users, quality of service guarantees, long ranges of up to 50 km, and broad coverage areas supported by its tower infrastructure. Advantages over WiFi are also discussed such as better performance, quality of service, range, coverage, and security. Potential future uses of WiMAX include providing fixed wireless connections initially, then
Wi-Fi allows devices to connect to the Internet and send/receive data wirelessly within the range of a wireless access point. It provides freedom of movement and access to the Internet from various locations without wires. Common places to install Wi-Fi include airports, hotels, restaurants, coffee shops, and shopping malls to cater to users such as travelers, businesspeople, students, and others with laptops. Setting up a Wi-Fi network involves devices like access points, network switches, and wireless network cards or adapters.
This document provides information about Bharat Sanchar Nigam Limited (BSNL), the largest telecommunication company in India. It discusses BSNL's history, services offered, revenues, and recent agreements. It also describes the basic workings of a telecommunication network, including call setup between landlines and mobiles. Key components of the network like telephone exchanges, transmission systems, and technologies like GSM, CDMA, and optical fibers are explained at a high level.
The 5G architecture uses an entirely IP-based model to integrate various radio access technologies and provide quality service through cognitive radio technology. It converges different networks on a 5G MasterCore that can efficiently operate in parallel modes to control all networks and enable new combined services globally through an innovative World Combination Service Mode.
Data Center Storge Architecture comparison EMC VMAX vs HUAWEI 18000 seriesLachezar Georgiev
The document provides an overview of the HUAWEI OceanStor 18000 Series storage product. It highlights key features such as [1] full redundancy and disaster recovery capabilities to ensure continuity of critical services, [2] flexible scalability and top performance specifications, and [3] intelligent software solutions for efficient resource allocation and optimization. The document also reviews the product's technical specifications, architecture, and how it addresses various application scenarios through solutions like SmartTier, SmartMotion, SmartQoS, and SmartPartition.
Wireless LANs (IEEE 802.11) allow devices to connect to a local area network using wireless transmission methods, providing flexibility, portability and mobility over wired LANs. The IEEE 802.11 standard published in 1997 defines the physical and data link layer specifications for WLANs. It has benefits like interoperability, fast development and price reductions. Common applications of WLANs include use in medical, education and emergency response situations.
This is a simple and easy understandable presentation on the topic Femto cell that can be used to provide communication facilities in a rural areas through internet.
(1) BSNL provides various telecommunication services across India including landline, cellular, broadband, and enterprise solutions. (2) A telecommunication network consists of exchanges, distribution frames, and switch rooms to connect subscribers and route calls. (3) BSNL offers different internet technologies like leased lines, WiFi, GPRS, and broadband to provide high-speed connectivity to users.
Wi-Fi is a wireless technology that allows devices to connect to the internet and each other without wires. It uses radio waves to transmit and receive data over short distances. The main components of a Wi-Fi network are access points, Wi-Fi cards in devices, and security measures. Wi-Fi provides mobility, ease of installation, and flexibility but has limitations like interference, performance degradation, high power usage, and limited range. It has many applications beyond basic internet access like streaming, file sharing, and smart home device synchronization.
Femtocell is a small, low-power cellular base station designed for use in homes or small businesses. It connects standard mobile devices to a mobile operator's network using a residential broadband connection, extending cellular coverage indoors where it may otherwise be limited or unavailable. Femtocells improve coverage and network capacity while reducing costs for both end users and mobile operators. Security risks associated with femtocells include threats to user privacy, denial of service attacks, and potential for fraud but these can be mitigated through security measures like IPsec and authentication protocols.
Femtocells are small cellular base stations that operate in a licensed spectrum to improve indoor wireless coverage. They connect to the mobile network via a user's home internet connection. Femtocells offer benefits like improved voice and data quality for users and increased network capacity for operators by offloading traffic. However, challenges remain around interference management, mobility, and regulatory issues regarding spectrum usage. As femtocell technology evolves, it has the potential to provide widespread indoor coverage and high data rates to meet future network demands.
This document provides a detailed study on femtocells. It begins with an introduction that defines a femtocell as a small cellular base station for use in homes or small businesses that connects to a service provider's network via broadband. The history section then discusses the early development of femtocell technology from 2002-2007. It proceeds to explain how femtocells work and their technical benefits for both users and operators, such as improved indoor coverage, reduced costs, and increased network capacity and coverage. The document defines femtocells and differentiates them from picocells and WiFi. It also outlines femtocell features, user benefits, and operator benefits. In conclusion, it discusses how femtocells extend high-data rate
Wireless networking in schools provides mobility for students and supports e-learning. It allows students to access the curriculum and research resources from anywhere in the school using devices like laptops and tablets. Wireless networks eliminate the need to run cables and wires, making installation faster and more flexible. They also reduce costs compared to wired networks. While wireless improves access and mobility, schools must also implement security measures to protect their network and devices on it. Newer wireless standards like 802.11ac provide faster speeds and greater capabilities to meet the needs of students' use of technology in schools.
LTE-A HetNets using Carrier Aggregation - Eiko Seidel, CTO, Nomor ResearchEiko Seidel
LTE-Advanced standardisation in Release 10 was completed in early 2011 and commercial network deployments using first Release 10 features are likely to be announced later this year. One of the most attractive features of LTE-A is Carrier Aggregation, where a user equipment (UE) might be scheduled across multiple carriers. Besides this, Heterogeneous Networks (HetNet) using small cells gained a lot of interest recently due to their potential to increase network capacity. This white paper provides some insight into how LTE-A HetNets with or without a centralized architecture might be deployed today and in the future, in particular in combination with Carrier Aggregation.
Seminar Presentation on Femtocell Technology
A femtocell is a small device that is used to improve
wireless coverage over a small area, mostly indoor. It is a small cellular base station, also
called a wireless access point that connects to a broadband Internet connection and broadcasts
it into radio waves in its area of coverage.
This document provides an overview of Wi-Fi technology, including its standards, network elements, configurations, applications, security threats and advantages/disadvantages. It discusses the IEEE 802.11b, 802.11a and 802.11g wireless standards and how they operate at different speeds and frequencies. It describes the basic components of a Wi-Fi network including access points and Wi-Fi cards. It also summarizes different Wi-Fi network topologies and security threats like eavesdropping, man-in-the-middle attacks and denial-of-service.
This 3 sentence summary provides the high level information about the document:
The document discusses Bharat Sanchar Nigam Limited (BSNL), India's state-owned telecommunications company. It covers the basic workings of a telecommunications network, components of BSNL exchanges like the main distribution frame, and mobile communication technologies used by BSNL like GSM, GPRS, CDMA. The document also discusses internet services provided by BSNL including broadband, WiMAX, FTTH and provides an overview of optical fiber transmission systems.
Bharat Sanchar Nigam Limited (BSNL) is India's largest telecommunications company that provides various telecom services across India. It operates through telephone exchanges that house switching equipment to facilitate call connections. The exchanges have different components like the main distribution frame for fault removal, power plants for electricity supply, and switch rooms containing cabinets for routing calls. BSNL also offers broadband internet through technologies like ADSL that provide high-speed connectivity to customers via the existing telephone network infrastructure.
Pankaj KR Purbey underwent a 14-day vocational training in basic telecommunications at RTTC BSNL in Guwahati. The document provides an overview of BSNL services and telecommunication networks in India. It discusses the architecture of telecom networks including user equipment, access networks, switching networks, and transmission networks. It also describes the key networks operated by BSNL including landline, mobile, WLL, internet/broadband, ISDN, and data networks. The document further explains concepts of multiplexing including FDM, WDM, and TDM. It provides details of pulse code modulation techniques involving filtering, sampling, quantization, encoding, and multi-frame structures
5G/NR wireless communication technology overview, architecture and its operating modes SA and NSA. Also an introduction to VoNR and other services overview of 5G network.
The key technologies of 5G namely MIMO and Network slicing are also explained.
Femtocell technology provides improved indoor mobile phone coverage and capacity. A femtocell is a small cellular base station that connects standard mobile devices to a mobile operator's network using a residential broadband connection. Femtocells enhance signal quality and coverage for mobile users inside homes and offices by establishing a mini cellular network connected to the macro network of the mobile operator. They offer benefits like improved coverage, increased network capacity, and a better user experience for calls made indoors.
This document discusses WiMAX (Worldwide Interoperability for Microwave Access), a wireless technology that provides broadband connections over long distances. It operates using towers and receivers. WiMAX works by transmitting signals from towers that can cover large areas, up to 50 km. Receivers pick up the signal and can be internal cards or external boxes. The document outlines key features of WiMAX including scalability to support thousands of users, quality of service guarantees, long ranges of up to 50 km, and broad coverage areas supported by its tower infrastructure. Advantages over WiFi are also discussed such as better performance, quality of service, range, coverage, and security. Potential future uses of WiMAX include providing fixed wireless connections initially, then
Wi-Fi allows devices to connect to the Internet and send/receive data wirelessly within the range of a wireless access point. It provides freedom of movement and access to the Internet from various locations without wires. Common places to install Wi-Fi include airports, hotels, restaurants, coffee shops, and shopping malls to cater to users such as travelers, businesspeople, students, and others with laptops. Setting up a Wi-Fi network involves devices like access points, network switches, and wireless network cards or adapters.
This document provides information about Bharat Sanchar Nigam Limited (BSNL), the largest telecommunication company in India. It discusses BSNL's history, services offered, revenues, and recent agreements. It also describes the basic workings of a telecommunication network, including call setup between landlines and mobiles. Key components of the network like telephone exchanges, transmission systems, and technologies like GSM, CDMA, and optical fibers are explained at a high level.
The 5G architecture uses an entirely IP-based model to integrate various radio access technologies and provide quality service through cognitive radio technology. It converges different networks on a 5G MasterCore that can efficiently operate in parallel modes to control all networks and enable new combined services globally through an innovative World Combination Service Mode.
Data Center Storge Architecture comparison EMC VMAX vs HUAWEI 18000 seriesLachezar Georgiev
The document provides an overview of the HUAWEI OceanStor 18000 Series storage product. It highlights key features such as [1] full redundancy and disaster recovery capabilities to ensure continuity of critical services, [2] flexible scalability and top performance specifications, and [3] intelligent software solutions for efficient resource allocation and optimization. The document also reviews the product's technical specifications, architecture, and how it addresses various application scenarios through solutions like SmartTier, SmartMotion, SmartQoS, and SmartPartition.
Wireless LANs (IEEE 802.11) allow devices to connect to a local area network using wireless transmission methods, providing flexibility, portability and mobility over wired LANs. The IEEE 802.11 standard published in 1997 defines the physical and data link layer specifications for WLANs. It has benefits like interoperability, fast development and price reductions. Common applications of WLANs include use in medical, education and emergency response situations.
This is a simple and easy understandable presentation on the topic Femto cell that can be used to provide communication facilities in a rural areas through internet.
Femtocells are low-power cellular access points that provide improved 3G coverage and bandwidth for mobile users making voice and data calls indoors. They connect to the mobile network via a customer's broadband connection, extending network capacity without requiring expensive infrastructure upgrades. Femtocells allow carriers to increase revenue from indoor mobile usage by enabling new services like mobile TV, music streaming, search tools and more to deliver a high-quality mobile experience for customers both inside buildings and out.
Femtocell is a low power, small base station in telecommunications. This cellular station is generally used for small businesses or home purposes. Femtocell is known as small cell in telecommunication industry. This base station uses connections like DSL or cable broadband to connect to other networks
iaetsd Approach of femto cell with battery backupIaetsd Iaetsd
The document proposes adding battery backup to femtocell devices to ensure continuous signal availability. Femtocells are small cellular base stations deployed by end users that provide improved indoor coverage, but their signals depend on the user's external power. To address this, the document suggests integrating a rechargeable battery into femtocells to power them for up to 14 hours during power outages. This would make femtocell signals continuously available to mobile users, overcoming their main disadvantage compared to traditional macro cell base stations.
“Design of Efficient Mobile Femtocell by Compression and Aggregation Technolo...Virendra Uppalwar
This document summarizes a presentation on designing efficient mobile femtocell networks through compression and aggregation technology. It discusses how small cells like femtocells can improve indoor coverage and capacity by offloading traffic from macrocells. It covers the evolution of cellular network technology to smaller cell sizes, benefits of femtocells for operators and users, and how femtocells work by establishing a connection through a user's home broadband connection. The presentation then describes a proposed methodology for a research project that would use network simulation and data compression/aggregation techniques to improve spectral efficiency when deploying mobile femtocell nodes.
This document provides an introduction to small cells, including:
1) Small cells are low-powered radio access nodes that operate in licensed and unlicensed spectrum with a range of 10 meters to several hundred meters, contrasting with typical macrocells with ranges up to tens of kilometers.
2) Small cells include femtocells, picocells, microcells and metrocells and operate in licensed spectrum managed by mobile operators.
3) The role of small cells is to tackle challenges of deployment such as finding appropriate sites, delivering power and backhaul, and managing interactions between small cells, macrocells and other wireless technologies.
Small Cell is a term that refers to low-powered cellular access points, including femtocells, picocells, and microcells. They have a range of 10 meters to several hundred meters, in contrast with traditional macrocells that can have a range of tens of kilometers. Small cells operate in licensed spectrum and are managed by cellular operators. They help improve coverage, capacity, and services for indoor environments like homes and businesses. Standards are being developed by 3GPP, 3GPP2, and other standards bodies to support small cell deployments across different wireless technologies.
The document discusses femtocell technology. A femtocell is a small cellular base station designed for use in homes or small businesses. It connects to a service provider's network via broadband and allows service providers to extend cellular coverage indoors or in areas where coverage would otherwise be limited. Many mobile network operators have launched femtocell services. Femtocells are plug-and-play devices that individuals can install themselves without technical expertise. Standards bodies have published specifications for femtocells to work with technologies like WCDMA, CDMA2000, LTE and WiMAX.
Wireless communication allows devices to transfer information without being physically connected by wires. There are four main characteristics for communication devices: fixed and wired, mobile and wired, fixed and wireless, and mobile and wireless. The most interesting case is mobile and wireless, where no cable restricts the user who can roam between different wireless networks using technologies like radio waves, light, or electromagnetic induction over various ranges. Common wireless technologies discussed include Wi-Fi networks, mobile communication systems, and Bluetooth for short-range transfers.
This document discusses mobile data offloading using femtocells and WiFi. It provides an overview of femtocell technology compared to WiFi offloading, explaining how femtocells can extend coverage and increase capacity by handling indoor data traffic. The document also outlines some of the challenges in implementing femtocell networks, such as interference management, quality of service, and network synchronization.
Small cells are Low-powered radio access nodes, Operate in licensed and unlicensed spectrum, Short range mobile phone base stations, Range from very compact residential femto-cells of area 10 meters to larger equipment used inside commercial offices or outdoor public spaces of area 1 or 2 kilometers, "small" compared to a mobile macro cell, with range of a few tens of kilometers, Complements mobile phone service from larger macro cell towers, Offer excellent mobile phone coverage and data speeds at home, in the office and public areas for both voice and data, Developed for both 3G and the newer 4G/LTE radio technologies.
Femto cells are Initially designed for residential and small business use with a short range and a limited number of channels. Femtocell devices use licenced radio spectrum. Femto cells must be operated and controlled by a mobile phone company, One cell with one mobile phone operator. When in range, the mobile phone will detect cell and use it in preference to the larger macrocell sites. Calls are made and received in exactly the same way as macrocell. Except, the signals are sent encrypted from the small cell via the public or private broadband IP network to one of the mobile operators main switching centres.
Femtocells are small cellular base stations that connect to a service provider's network via broadband to improve indoor cellular coverage. They allow service providers to extend network coverage inside homes and businesses without expensive cellular towers. Femtocells route mobile phone traffic through the IP network to decrease costs for service providers. They typically support 2-5 mobile phones in residential settings. Femtocells were first conceptualized in 2002 and gained momentum in 2004 as companies investigated their potential. The Femto Forum was established in 2007 to promote femtocell adoption. Femtocells provide benefits like improved coverage and capacity for network providers as well as enhanced service, rates, and satisfaction for subscribers.
It was about Femto cells . When we have a major problems in wireless communication and there is a weak signal received by mobile station , we talk about femto cell which overcome this obstacle and cover a specific area that have the weak signal .
This document provides a literature review on topological planning of heterogeneous mobile networks in dense areas. It discusses the need for heterogeneous networks using a mix of macro, pico, femtocell and relay base stations. The network architecture is presented, including different types of base stations and their characteristics. Challenges of network planning in dense areas are also addressed, such as mitigating interference between indoor base stations and outdoor macrocells. Pathloss models and different interference scenarios are reviewed to understand their impact on network capacity and coverage optimization.
This document discusses femtocells, which are small cellular base stations installed in homes to improve indoor mobile phone reception. It summarizes that femtocells connect directly to the cellular network instead of relying on outdoor macrocell towers, enhancing call quality when indoors. The document also examines femtocell integration into 3G network architectures and interference issues that may arise between femtocells and macrocells operating in limited licensed spectrum bands.
1) Passive optical networks (PONs) that support both business and residential customers on the same network architecture are now economically feasible, as they can help share the high costs of building out the last mile of fiber infrastructure.
2) Integrating business and residential applications on a single PON can increase overall revenue per line and make building the expensive last mile infrastructure more affordable.
3) A PON network mixes business and residential traffic on the same fiber infrastructure from optical network terminals (ONTs) at customer premises through an optical distribution network to a central office, where an optical line terminal directs traffic to appropriate switches.
The document discusses 3G Femto Home Access, which uses small low-power 3G base stations (Femto cells) connected to residential broadband to provide excellent 3G coverage and capacity in users' homes. This is seen as the third wave of indoor coverage solutions that can reach the mass consumer market through a plug-and-play approach. An open and standardized architecture is proposed using Iu interfaces and a new Femto Gateway network element to connect Femto cells independently of the macro network in a scalable way.
Interference Aware & SINR Estimation in Femtocell NetworksIOSR Journals
This document discusses technical challenges in deploying femtocell networks. It describes how femtocells can help address issues with indoor coverage and capacity demands. However, interference management is a major challenge as femtocells and macrocells share the same licensed spectrum. There are two types of interference: co-tier between neighboring femtocells, and cross-tier between femtocells and macrocells. Effective interference mitigation techniques are needed to allocate subcarriers and reduce interference, in order to improve network throughput and prevent "dead zones" of degraded quality of service.
This document provides an overview of Bharat Sanchar Nigam Limited (BSNL), India's state-owned telecommunications company. It discusses BSNL's services, the basic workings of a telecommunications network including call setup and network components. It also summarizes key networking concepts like CDMA, GSM, fiber optics, IP addressing, and the OSI model. The document is intended as an industrial training seminar on BSNL submitted by a student.
1. FEMTOCELL TECHNOLOGY
A SEMINAR REPORT
Submitted in partial fulfillment of the requirements for the award of degree of
BACHELOR OF TECHNOLOGY
in
APPLIED ELECTRONICS AND INSTRUMENTATION
by
HAREESH P(GCAMEAE025)
DEPARTMENT OF APPLIED ELECTRONICS AND
INSTRUMENTATION
GOVERNMENT ENGINEERING COLLEGE
KOZHIKODE - 673 005
MARCH 2016
2. GOVERNMENT ENGINEERING COLLEGE
KOZHIKODE - 673 005
DEPARTMENT OF APPLIED ELECTRONICS AND
INSTRUMENTATION
CERTIFICATE
This is to certify that the seminar report entitled “Femtocell technology” was
presented by HAREESH P (GCAMEAE025) in partial fulfilment of the
requirements for the award of degree of Bachelor of Technology in Applied
Electronics and Instrumentation under Calicut University during the year 2015-2016
at Govt. Engineering College, Kozhikode.
Head of the Department: Co-ordinators:
Prof. Rishidas S Dr. Abdul Hameed K M Deepak K S
Associate Professor & HOD Professor Assistant Professor
Dept. of AE&I Dept. of AE&I Dept. of AE&I
Govt. Engineering College Govt. Engineering College Govt. Engineering College
Kozhikode – 5 Kozhikode – 5 Kozhikode - 5
Place:
Date:
3. Abstract
The last few years have seen tremendous growth in mobile network and telecommunications. Since
there are over four billion mobile phone users in the world today, and the numbers continue to rise.
Mobile cellular and 3G networks normally suffer from poor penetration and reception in certain
areas, like indoors. This decreases the quality of voice and video communication and there by slow
down the high speed services. In order overcome these kind of issues femtocell technology has
been introduced. This allows users to make free calls through internet, thereby acting as potential
threat to mobile operators around the world.In order to overcome these kinds of issues femtocell
has been developed. A femtocell is a device that is used increase the wireless coverage over a small
area, mostly indoor. It is a small base station which is installed in homes. They are similar in size
to a router and offer better signal coverage. Femtocell is connected to mains power and a standard
broadband IP connection through to the mobile operator’s network. It is simply a plug-and-play
device, that a user can easily plug it to a broadband connection. Whenever a user enters into their
home the femtocell will detect the mobile handset and vice versa and a connection will be
established. The name femtocell has the prefix 'femto', meaning a very small cell (area of network).
All calls are then made via femtocell. A broadband connection is a prerequisite for connecting a
femtocell. The femtocell enables the encryption for all voice calls and data sent or received by the
mobile phones. This will protect the breaking of user’s home network by the external user. To a
standard 3G cellular phone, the femtocell appears as another cell site or macro cell, hence
communicating with it as it would with a macro cell, when the mobile is used in outdoors. Since
femtocells operate at very low radio power levels, battery life is high and typically has a range of
200 meters. Also as the distance between the femtocell and mobile handset is short, quality of call
will be excellent. Femtocells from part of the mobile operation’s network, although they are
located at home or in the business. Most of the functionality of a completer 3G cell site has been
miniaturized onto a chip, which look and operates like a Wi-Fi access point, and is connected via
broadband DSL back to the mobile operator’s network. A femtocell is installed at home and
connected to mains power and a standard broadband IP connection (typically DSL) through to the
mobile operator’s core network. Voice calls, text messages and data services are provided by the
same systems. Femtocells operate at very low radiation power levels (50 mill watts peak output
during a call, much lower when idle), and typically have a range of 200 meters.
4. 1. INTRODUCTION
Mobile operators have been searching for licensed indoor coverage solutions since
the beginning of wireless networks. Unfortunately, the bulk of this opportunity (i.e.
residential environments) has been beyond the addressable market for cost and operational
reasons. These reasons has triggered the design and development of new cellular standards
such as WiMax (802.16e),the third generation partnership project’s(3GPP’s)High speed
packet access(HSPA)and LTE standards, and3GPP2’s EVDO. In parallel, WiFi mesh
networks are also being developed to provide high-rate data services in a more distributed
fashion. Although the Wi-Fi networks will not be able to support the same level of mobility
and coverage as the cellular standards, to be competitive for home and office use, cellular
data systems will need to provide service roughly comparable to that offered by Wi-Fi
networks.
The recent technology is femto cell, the main aim of femto cell is to improve
coverage and capacity of a mobile network by allowing service providers to extend service
coverage indoors, especially where access would otherwise be limited or unavailable. A
femto cell is a very small base station. so small, infect that can be placed in a customer’s
residence. Femto cells are low-power access points that can combine mobile and Internet
technologies within the home. The femto cell unit generates a personal mobile phone signal
in the home and connects this to the operator’s network through the Internet. This will
allow improved coverage and capacity for each user within their home.
5. 2. FEMTOCELLS
2.1 DEFINITION AND CONCEPT OF FEMTOCELL
Femtocells are low-power wireless access points that operate in licensed spectrum
to connect standard mobile devices to a mobile operator’s network using residential DSL
or cable broadband connections.
Concept of femtocell
A femtocell is a very small base station. So small, infect that can be placed in a
customer’s residence as shown in figure 1. The femtocell unit generates a personal mobile
phone signal in the home and connects this to the operator’s network using standard
broadband DSL on Cable service and typically supports 2 to 5 mobile phones in a
residential setting. This will allow improved coverage and capacity for each user within
their home.
Figuer1. Femtocell concept
6. 2.2 Need for femtocell
Third-generation cellular technology suffers from inadequate indoor-signal
penetration, leading to poor coverage in the environment where consumers spend two-
thirds of their time. Poor coverage diminishes the quality of voice and video applications,
and slows down high-speed data services
To keep customers satisfied, 3G carriers have increased capacity by building
additional microcell sites. This strategy is becoming much less attractive. Site acquisition
costs are exorbitant and continue to mount as space on viable towers and buildings fills up,
landlords exact high rents and regulators impose onerous permit requirements. Public
opposition to the building of large-scale base stations is increasingly common.
Acquiring a site is only half the battle: Sophisticated base station equipment must
then be purchased, installed, insured, operated and maintained. The net present value of a
cell site in the U.K. is estimated to be $500,000. Carriers thus face a serious dilemma
Well it's clear more and more consumers want to use mobile phones in the home,
even when there’s a fixed line available. Friends and family usually call a mobile number
first, and it’s where messages and contact lists are stored.
However, it is often the case that providing full or even adequate mobile residential
coverage is a significant challenge for operators.
From a competitive perspective, femtocells are important because mobile operators
need to seize residential minutes from fixed providers, and respond to emerging VoIP and
WiFi offerings.
resources. It also enables capacity equivalent to a full 3G network sector at very low
transmit powers, dramatically increasing battery life of existing phones, without needing
to introduce WiFi enabled handsets.
7. 2.3 Classification of femtocells
Since a large number of femtocells can be installed by subscribers, in certain
scenarios femtocell access shall be restricted to certain subscribers who are authenticated
and authorized for exclusive access and related network service.
Additionally, femto BS can provide a mechanism delivering initial access
information (e.g. BS ID, frequency, closed group information, NSP, roaming capability)
of it’s own and neighboring femto BSs to any MSs in order to facilitate their network
discovery/selection and entry procedure to femtocells.
Femto BS can be classified into 4 types:
Based on bearer connection capability
Open femto BS : Provides bearer connectivity (full network services) to any MS
Closed femto BS : Only provides bearer connectivity to allowed (identifiable)
MSs
Based on initial access information capability
Initial access able femto BS : Provides initial access information for any MSs.
3. FEMTOCELL WORKING
Femtocells from part of the mobile operation’s network, although they are located at home
or in the business.
Most of the functionality of a completer 3G cell site has been miniaturized onto a chip,
which look and operates like a WiFi access point, and is connected via broadband DSL back to the
mobile operator’s network. A femtocell is installed at home and connected to mains power and a
standard broadband IP connection (typically DSL) through to the mobile operator’s core network.
Voice calls, text massages and data services are provided by the same systems.
8. Femtocells operate at very low radiation power levels (50 milliwatts peak output during a
call, much lower when idle), and typically have a range of 200 meters. The signals do not travel
through walls particularly well, but this is a benefit because it allows the frequency to be reused
for other calls in nearby building. Where users walk outside or out of range, calls are automatically
handed over to the external mobile network. Any standard 3G phone can be used on the femtocell
if permitted by the mobile operator. Unlike WiFi access points, 3G Femotcells operate using
licensed spectrum and thus must be supplied and operated in conjunction with the mobile operator
Figure 1 shows working of femtocell.
The battle is most likely to be between the modified 3G RAN (which some RAN Network
vendors are keen to promote because it reuses their existing RNC products) versus UMA, which
has new, custom designed systems architected to handle the much larger number of cells and IP
connectivity. SIP based solutions may be of interest wherethe user wants to bypass the network
operator completely, and is happy to operate in a different way to achieve this.
Figure 3. Femtocell work
9. 4. HANDOVER OPERATION
Handover (called handoff in the US) is the process by which a mobile phone
switches between different call sites during a phone call, continuing with seamless audio in
both directions. One of the most complex aspects of mobile phone systems, Femtocell users need
this capability when entering or leaving their home – perhaps a rare use case, but essential
nonetheless.
4.1 Handover in Mobile Phone systems
As a person move around when on a call, your mobile phone continuously measures
the signal level and quality from nearby cell sites. These measurement reports are streamed
to the current active base station, which determines when and where to initiate a handover
sequence. Complex algorithms are used when making these judgments, in order to ensure
that best use is made of all available capacity while reducing the likelihood of dropping a
call during (or by postponing) a handover.
In the case where connection to the current active cell site is dropped, the system is
smart enough to allow the mobile phone to request a new connection on a different cell site
and reconnect the call. This typically causes a short break of up to a few seconds in the
conversation. If the call cannot be reconnected, then it drops out.
3G systems are slightly more complex because it is possible for a mobile to be
actively connected to more than one cell site at the same time. This feature, called soft
handover, allows the same signal transmitted by a mobile phone to be picked up by multiple
cell sites and the best quality reception selected on a continuous basis.
4.2 Femtocell Handover
Femtocells do not implement soft handover, regardless of the radio technology
used. Instead, all calls are switching instantly to or from the femtocell and the external
outdoor cellular network. This is known as “hard handover” and would typically not be
audible or noticeable to the caller.
10. The 2G and 3G systems from the same mobile network co-exist, as is very common
with GSM and UMTS, and then handover between 2G and 3G can also occur. Operators
prefer to use 3G systems because of the higher traffic capacity and lower costs. Their
systems are therefore configured to automatically select 3G where good reception is
available, reverting to 2G when out of coverage – typically either in a rural area or inside
building where 3G signals can’t so easily penetrate (due to operating at higher frequencies
and having fewer 3G call sites thus being further away).
Many 3G femtocells are also capable of 2G GSM reception. 2G typically penetrates
buildings better than 3G, it allows the femtocell to determine where it is (by reading the
cell site identification on its broadcast channel), derive some timing/clocking reference (as
one input to its timing algorithm), and work out which 2G cell sites might be most
appropriate to handover to when a mobile phone leaves the femtocell zone. Presumably,
these 2G cell site identifies can then be transmitted to the mobile phone as potential
handover candidates (known as the neighbor list), and be measured during any active call
in case a handover is requied.
Femtocells do not implement soft handover, regardless of the radio technology used.
Instead, all calls are switching instantly to or from the femtocell and the external outdoor
cellular network. This is known as “hard handover” and would typically not be audible or
noticeable to the caller.
The 2G and 3G systems from the same mobile network co-exist, as is very common
with GSM and UMTS, and then handover between 2G and 3G can also occur. Operators
prefer to use 3G systems because of the higher traffic capacity and lower costs. Their
systems are therefore configured to automatically select 3G where good reception is
available, reverting to 2G when out of coverage – typically either in a rural area or inside
building where 3G signals can’t so easily penetrate (due to operating at higher frequencies
and having fewer 3G call sites thus being further away).
11. Many 3G femtocells are also capable of 2G GSM reception. 2G typically penetrates
buildings better than 3G, it allows the femtocell to determine where it is (by reading the
cell site identification on its broadcast channel), derive some timing/clocking reference (as
one input to its timing algorithm), and work out which 2G cell sites might be most
appropriate to handover to when a mobile phone leaves the femtocell zone. Presumably,
these 2G cell site identifies can then be transmitted to the mobile phone as potential
handover candidates (known as the neighbor list), and be measured during any active call
in case a handover is requied.
1. Adding femtocells to the neighbor lists of the outdoor macro cells: This is
unlikely to be as scalable or workable solution. Although neighbor lists can be quite large,
the time taken to scan round many different settings increases proportionally. In dense
urban areas, there may potentially be some 100’s of femtocells colleocated with an outdoor
macro cell. The mobile phone would not be searching for the most likely cell site to switch
over to, and dropped calls would increase. Additionally, the complex management to
download and maintain vast numbers of femtocell candidates add an overhead to the
network operator.
2. Adding some smarts into the mobile phone:One of the key benefits of femtocells
is that they work with any standard 3G phone – this is a clear competitive advantage
compared with WiFi dual-mode solutions that are restricted to specific (and sometimes
more expensive) dual mode devices. However, it could be argued that with some additional
functionality in the phone itself, then improved handover into the femtocell zone is enabled.
For example, the phone could learn about its femtocell zone and the matching external cell
site used outside. When on a call in the external cell site it could additionally monitor for
the femtocell and switch across to it when in range.
3. Making the femtocell as clever as possible: Ensuring that any calls about to
dropout when entering the femtocell zone are quickly restored as soon as the mobile can
detect and lock-on to the femtocell. Parameter selected by the femtocell, such as the cell-
12. ld and paging zone, can encourage more rapid identification. Someoptimization may be
required in the mobile network too, but the idea would be to avoid any changes to the
mobile phone itself. This is one area where femtocell vendors will be able to differentiate
themselves.
5. DESIGN OF FEMTOCELL
The following are the key features that are to be considered as the characteristics of
femtocell in the design of femtocell.
Low-impact – Space may be limited for some households. As a result femtocells must be
physically small, ideally aesthetically pleasing and easy to position. Furthermore, they should also
be silent in operation, generate low levels of heat output and inexpensive to run in terms of on-
going [electricity] cost.
Low RF power – The transmit RF power output of femtocells is low; between 10 and 100
milli-watts. Put in perspective, this is a lower power level than many Wi-Fi access points, which
can be specified up to 1 Watt of output power. Additionally, by being close to the femtocell the
3G handset is itself able to transmit at lower power levels than it might otherwise have to when on
the macro network.
Capacity – Femtocells are aimed at delivering dedicated 3G coverage to a household and
in doing so can provide a very good end-user experience within the home environment. As a result,
femtocells have a design “capacity” of up to 6 end-user.
Low-cost – There is significant competition for access solutions in the home space. Wi-Fi
is commonplace, easy to install/configure, provide a very good benchmark in terms of
performance, and are highly cost effective. Femtocells will be offered for purchase via their
Operators. This may be direct or through resellers.
Energy offset - Low-power consumption – Clearly if the end-user is to foot the bill for the
electrical energy consumed by the femtocell base-station then this figure must be low enough not
13. to raise concerns as to its impact on the fuel bill. That said, from an Operator’s perspective, this
OPEX is effectively offloaded, which makes the business case for femtocells even more attractive.
Easy end-user installation – Like cable modems and DSL routers, femtocells will be
installed by consumers and activated through service providers. This means that the Operator no
longer has to employ installation teams or have a truck-roll every time a new femtocell is
“deployed”. From the end-user perspective the unit must be a simple “plug and play” installation
with a minimal amount of intervention required.
Backhaul via broadband– Femtocells utilize Internet protocol (IP) and flat base-station
architectures. Backhaul connection to Operator networks will be through wired broadband Internet
service existing in the home such as DSL, cable, or fiber optics as available. There are no
connections required to the wider cellular network other than through the IP core. This will benefit
Operators by effectively offloading traffic that would otherwise be on the macro-layer directly
onto the internet from the femtocell; this not only reduces the load on the core network but also
lowers the cost of delivering wireless traffic when compared to the macro network.
Interference - The use of femtocells in spectrum also currently used by the macro layer
may, if not managed correctly, give rise to issues with interference between cells; macro with
femtocell and in the instance of close proximity of two or more units, femtocell with femtocell.
Operators will likely want to launch femtocells on the same channel as their macro cell network
for capacity reasons.
Handovers - Current macro RF planning techniques are inappropriate for femtocells. Not
least because of the sheer potential numbers of femtocells and managing the neighbor lists that
would be necessary. Also the potential to “ping-pong” between layers, especially as an end-user
moves around the home and enters into areas where the signal strength from the macro-cell is
greater than that of the femtocell, must be considered very carefully to ensure that the networks
provide the best overall coverage without issue. To illustrate, in macro based 3G networks the
overhead associated with soft-handovers accounts for a significant proportion of RNC processing
capability. Understandably then and in order not to exacerbate the issue, great care and
14. sophisticated algorithms are necessary to overcome these potential issues and ensure that the over-
all network quality is not impacted by inefficient handovers and wasted capacity.
Security - Given the requirements for low-cost and easy installation, the use of the
broadband internet as the network interface becomes very easy to understand. However this raises
security risks in that broadband internet has open access. There are various approaches to address
this issue including the embedding of the Iub interface within the IP signaling itself while network
security is managed by the IP security (IPSec) protocol.
Worldwide cellular network standards support – Understandably femtocell products
are likely to appeal to many end-users around the world. As a result differing models will be
developed and offered to satisfy the various needs from the different regions. Products will offer
support for their respective and existing (3GPP) UMTS and (3GPP2) CDMA standards, as well as
emerging standards such as WiMAX, UMB and LTE.
Support for existing 3G handsets and devices –Support for existing handsets and devices
is a very important consideration for the end-user and Operator alike, not least because of the cost
of changing devices if that were necessary. In each technology market, femtocells will support
existing handsets and devices further helping to drive uptake of 3G services and femtocells in
particular.
Operation (transmit/receive) in Operator-owned spectrum – Femtocells operate in
licensed spectrum owned by Operators and may share the same spectrum (currently the 2100MHz
frequency band) with the macro network.
Operator controlled – Femtocells operate in licensed spectrum and as such Operators
must ensure that they comply with the conditions of that license and any other controls enforced
by a regulator. To these ends femtocells feature client software that enables remote configuration
and monitoring via an Operations, Administration, Maintenance and Provisioning (OAM&P)
system in a similar manner to that used by the macro network.
15. New services and applications – Femtocells are likely to become an integral part of
managing all communications in and out of the home environment. Femtocells enable Operators
to cost-effectively offer in-home pricing and integrate mobile services into triple-play / quad-play
service offerings. Femtocell architectures include provision for a services environment on which
applications may be added, thereby facilitating new revenue opportunities.
Service Assurance – Remote Management to enable an operator to provide the end-user quality
of service at the edge of the network.
6. BENEFITS OF FEMTOCELLS
Due to the substantial benefits, femtocell technology is causing quite a “buzz” in
the industry. Research has forecasted that by 2011 there will be 102 million users of
femtocell products on 32 million access points worldwide.
Better coverage and capacity
– Due to short transmit-receive distance
Lower transmit power
Prolong handset life
Higher SINR
Higher spectral efficiency
Improved macro reliability
– BS can provide better reception for mobile users
Traffic originating indoors can be absorbed into femtocell networks over Ip
backbone
Cost Benefit
16. – $60,000/year/marcrocell vs. $200/year/femtocell
Reduced subscriber turnover
– Enhanced home coverage will reduce motivation for users to switch
Carriers
Capacity benefits of femtocell
– Reduced distance between sender and receiver leads to higher signal strength
[capacity improvement]
– Lowered transmit power decrease the Interference for neighboring cells
[capacity improvement]
– Femto-AP can devote a larger portion of resource for fewer users.
[frequency efficiency]
7. DISADVANTAGES
1. High price ($300).
2. Difficult to install.
(Cabling, roof access etc)
3. Dependent on signal from nearest cell town.
4. Requires broadband connection.
5. More complex to set up, requires a new/different phone number, more potential
for errors.
6. It does not provide good coverage in outdoors.
17. 8. APPLICATIONS
8.1 DSL Modem
The step is to integrate the femtocell into an existing DSL broadband modem design. No
additional external connections are needed – the modem will already have power and data
connectivity, and usually a list of other standard features too. The femtocell module is hardwired
into the modem and can be given priority of voice calls to ensure improved performance.
The overall cost of the combined unit is much less than two separate boxes, it is the ease
of installation and remote management which benefits this option. Many mobile operators have
started offering DSL broadband as an additional service, particularly in Europe. If the additional
cost of a combined modem/femtocell is acceptable, then this could be shipped to customers as part
of a package.
8.2 Cable Modem
More households in the USA receive their broadband internet service from their cable TV
supplier than from the phone company (as is more common in Europe and elsewhere). The modem
can be separate from the TV Set-top box or a combined unit.
The large Cable TV companies in the US, such as Comcast, previously had agreements to
resell mobile services on the Sprit network. This appears to have been discontinued. Although
Cable TV companies do own some spectrum (via the Spectrum Co) business, and so could legally
launch and operate a rather than traditional mobile phone.
18. 9. CONCLUSION
Femtocell is as an Access Point Base Station—is a small cellular base station, typically
designed for use in residential or small business environments. It connects to the service provider’s
network via broadband (such as DSL or cable); current designs typically support 5 to 100 mobile
phones in a residential setting. A femtocell allows service providers to extend service coverage
indoors, especially where access would otherwise be limited or unavailable.
http://en.wikipedia.org/wiki/Base_stationUnsatisfactory coverage and the increasing
number of high-data-rate application are two driving forces for femtocell development
Femtocells have the potential to provide high-quality network access to indoor users at low
cost
– improve coverage
– Provide huge capacity gain
From technical standpoint, some challenges shall be overcome
– New network architecture
– Interference mitigation
– Synchronization
– End-to-end QoS support
– Seamless handover support
Femtocells are an alternative way to deliver the benefits of Fixed Mobile Convergence. The
distinction is that most FMC architectures require a new (dual-mode) handset which works with
existing home/enterprise Wi-Fi access points, while a femtocell-based deployment will work with
existing handsets but requires installation of a new access point.