Summary
この調査レポートでは、LTEおよび5Gネットワークのセルラー容量およびカバレッジ最適化市場を評価しています。
主な掲載内容(目次より抜粋)
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エグゼクティブ・サマリー
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はじめに
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技術とアプリケーションの分析
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5Gスマートアンテナの市場ダイナミクス
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5Gスマートアンテナのエコシステム分析
Overview:
This research assesses the cellular capacity and coverage optimization market for LTE and 5G networks. It analyzes RF technologies including smart antennas and DAS as well as optimization techniques involving radio control systems. It also evaluates technologies and strategies for network densification including small cells and carrier WiFi. It provides forecasts for each major area from 2021 to 2026.
Purchasers of this research at the Multi-user License level or greater will also receive at no additional cost Private Wireless Networks Market by LTE, 5G, and Edge Computing in Enterprise, Industrial, and Government Solutions 2021 – 2026, which evaluates 5G NR and the market outlook for MNO and VNO to offer private IoT networks for the benefit of industrial automation and mission-critical enterprise applications and services. The report evaluates major players, technologies, and solutions.
Select Findings:
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Global multi-vendor SON platform market will reach $8.3 billion by 2026
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DAS market associated with 5G smart antennas will reach $6.51 billion by 2026
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Neutral hosts and private networks will be the fastest growing market opportunities
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Global small cell will reach $5.7 billion by 2026, driven by outdoor densification and indoor penetration solutions
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Global carrier WiFi will reach $4.2 billion by 2026 with Asia Pac leading followed by North America and Europe, driven in part by WiFi6 upgrades
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Increasing demand for enhanced mobile broadband capacity and coverage will continue to play a substantial role in carrier WiFi and small cell market’s growth
5G will bring about fundamental structural economic changes, such as significantly lower broadband pricing as a whole, and also much greater flexibility for enterprise, industrial, and government market segments in terms of how they connect public to private networks.
A Heterogeneous Network (HetNet) that is based on a combination of cellular small cells, macro cells and carrier Wi-Fi is expected to play a pivotal role in addressing the capacity needs for such a traffic surge in the mobile networks. HetNets are important drivers for the evolution of LTE and critical for 5G networks, which rely upon a greater number of shorter-range radio units for continuous communications.
Physics dictates that higher frequencies need more power and/or more coverage as an RF signal fades more than a lower frequency signal. This is why there will need to be at least an order of magnitude more antennas than required for LTE. Putting this into perspective, the United States will go from roughly 30,000 antennas to 300,000 or more nationally.
5G antennas will be found virtually everywhere in metropolitan areas, but it will not be enough. While dramatically increased coverage will surely support many early 5G applications, such as fixed wireless (ISP alternative, back-haul, and front haul), it will not be enough to support continuous 5G mobility coverage. This will be vitally important for certain applications such as self-driving cars and connected vehicle services.
In terms of deploying radio access network infrastructure, carriers seek to leverage cloud RAN topologies that include centralization of baseband processing units (BBU) that may serve multiple remote radio heads. This facilitates the control of BBU for many different sites on a remote basis. This type of 5G densification strategy optimizes resource utilization and provides various operational improvements such as the ability to upgrade BBUs for different sites without the need to dispatch personnel to each site.
Driven by the growing surge for mobile broadband, carriers worldwide are investing in WiFi and small cells as part of HetNet infrastructure to expand network capacity and coverage. Not only do WiFi and small cell deployments minimize network planning, redesign and real estate costs, they also allow carriers to avoid or minimize new frequency allocation costs. In many cases, small cells can utilize the same frequency spectrum that carriers have allocated for macro cell deployment, while WiFi access points leverage unlicensed spectrum.
The associated savings in both capital expenditures and operational expenses, combined with higher throughput rates, make WiFi and small cells a necessity for mobile network operators worldwide. We expect the carrier WiFi and small cells infrastructure market will grow at a brisk rate over the next ten years. However, the market still faces a number of serious challenges including but not limited to interference management, optimization and backhaul.
Smart antenna arrays use Multiple Input / Multiple Output (MIMO) at both the source (transmitter) and the destination (receiver) to improve signal quality. This is in contrast to non-array systems in which a single antenna (and signal path) is used at the source and the destination. The market for smart antennas is nothing new as they provide efficient coverage for 2G, 3G, and LTE. However, 5G smart antennas will be necessary to provide mobility support for many new and enhanced apps and services such as virtual reality, self-driving cars, connected vehicles, and voice over 5G.
Smart antennas will improve 5G coverage and optimize capacity by focusing RF signals where they are needed the most. In addition, smart antennas enhance 5G application and service mobility by facilitating a more continuous connection, which may become particularly useful at 5G coverage seams. Otherwise, a 5G enabled user experience may degrade as hand-over from 5G to LTE occurs.
5G cellular networks promise to improve many aspects of wireless communications, supporting enhanced mobile services, greater scalability for IoT systems, and ultra-reliable communications for mission-critical applications. A portion of these benefits will be based on the evolution of 4G LTE technologies as well as unique capabilities enabled by 5G New Radio (5GNR), based on new infrastructure supporting millimeter wave (mmWave) RAN equipment.
DAS represents a network of spatially separated antenna nodes, connected to a common source via a transport medium that provides wireless service within a geographic area or structure. DAS leverages Multiple Input Multiple Output (MIMO) technology, which allows networks to take advantage of multiple signals as a means of optimizing wireless communications.
A DAS installation includes antennas, control boxes, and fiber optics connected to a hub. These Nodes include small antennas that unobtrusively blend into their environment. Often deployed at existing public infrastructure (such as utility poles, light posts, and traffic signals), DAS networks rely upon the ability to seamlessly blend into their environment, which may be outdoor or indoors.
Relevant to DAS, Multiple Input Multiple Output (MIMO) technology commercially started with 802.11n, which has gained strong acceptance in networks with the launch of WiMAX and LTE operations. DAS will also be a very important component of 5G networks along with smart antennas, which rely upon certain RF propagation techniques such as beam-forming.
A key driver for improving OSS for LTE and 5G systems, the Self Organizing Network (SON) has been introduced as part of the network framework. We see SON having a dramatically positive effect on network operations and OSS.
SON is largely a software-only solution today. In other words, SON is not a physical solution (such as Remote Electrical Tilt solutions). Mobile optimization comes in many forms ranging from RF to QoS for data management and applications. SON and related technologies/solutions fill a key role as it provides the ability to provide both static and near real-time information. It is important to note that smart antennas, DAS, and cloud RAN are all in the same family of optimizing operations, but not considered all part of SON.
It is also important to recognize that smart antennas, DAS, and cloud RAN are all in the same family of optimizing operations, and while related (in the network optimization family), are not considered part of SON in the strictest sense. Working hand-in-hand with SON to optimize wireless networks, smart antennas provide simultaneous and efficient coverage for 2G, 3G, and LTE. This translates into higher throughput and improved coverage for when and where customers need it. While this is helpful in terms of pre-5G optimization, it will arguably become critical for the support of 5G network optimization and support for true 5G mobility with a continuous connection within a given coverage area.
Companies in Report:
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Airgain Inc.
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Airhop Communications
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Airspan
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Alcatel-Lucent Enterprise
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Amdocs
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American Tower Corporation
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Andrew
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ANSYS Inc.
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ArrayComm LLC
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Ascom Holding AG
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AT&T Mobility
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Axell
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BLiNQ Networks
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Boingo Wireless
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Broadcom Inc.
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Bwtech
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California Amplifier Inc.
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Cambridge Communication Systems Ltd.
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Casa Systems
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Cellwize Wireless Technologies Pte Ltd.
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China Mobile
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Cisco
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Cobham Antenna Systems
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Comarch
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Comba Telecom Systems Holding
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Comcast
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Commscope
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Corning
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Crown Castle
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Dali Wireless
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DAS Simplified
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Eircom
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Ericsson
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Essentia
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FoxCom
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Honeywell International Inc.
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Huawei Technologies Co., Ltd.
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iBwave
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InSite Wireless
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Intel Corporation
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iWireless
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KDDI
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Korea Telecom
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Laird Technologies
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Legrand
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Leica Geosystems AG
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Linx Technologies
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LOCOSYS Technology Inc.
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MediaTek Inc.
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Mera
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Microlab, FX
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Motorola Solutions Inc.
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NEC Corporation
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Nokia Corporation
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NTT DoCoMo
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NXP Semiconductors
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Optical Telecom
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Optus Australia
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P.I. Works
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PCTEL Inc.
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Qualcomm Incorporated
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RadiSys Corporation
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Reliance Communications
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Reverb Networks
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Rohde & Schwarz
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Ruckus Networks
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Samsung Electronics Co. Ltd.
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SFR France
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Siemens AG
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Sierra Wireless (Accel Networks)
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SingTel
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SK Telecom
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Smart Antenna Technologies Ltd
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Softbank Japan
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SOLiD
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Sprint (T-Mobile)
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TCS
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TE Connectivity
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Telefonica O2 UK
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Teoco Corporation
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Tim Brasil
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T-Mobile
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Tyco (TE Connectivity)
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U.S Cellular
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Verizon Wireless
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Viavi Solutions
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Vodafone
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Westell
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Zain Bahrain
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Zain Saudi Arabia
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ZHEJIANG JC Antenna Co. Ltd.
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ZTE Corporation
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Table of Contents
Table of Contents:
5G Smart Antenna Market by Type (Switched Multi-Beam Antenna and Adaptive Array Antenna), Technology (SIMO, MISO, and MIMO), Use Case, Application, and Region 2021 – 2026
1. Executive Summary
2. Introduction
2.1 What Makes an Antenna Smart
2.2 Smart Antenna Systems
2.3 Smart Antenna Benefits
2.4 Smart Antennas for 5G
2.4.1 Electronically Scanned Arrays and Phased Antenna Array Design
2.4.2 Slot Coupled Microstrip Patch Antenna Array Synthesizer App
2.5 Smart Antenna Techniques
2.5.1 Fixed Switched Beam Arrays vs. Directional Finding Arrays
2.5.2 MRC, STBC, and Spatial Multiplexing
2.5.3 SIMO, MISO, and MIMO
2.5.4 Space Division Multiple Access
2.5.5 Random Beamforming
2.6 Smart Antennas Market Factors
2.7 Smart Antennas Shipment and Sales
3. Technology and Application Analysis
3.1 Smart Antenna Types
3.1.1 Switched Multi-beam Antennas
3.1.2 Adaptive Array Antennas
3.2 Digital Antenna Array
3.3 5G NR Infrastructure and Active Antennas
3.4 Mobile Device Antennas
3.5 System Connectivity
3.6 Adaptive Beamforming
3.6.1 Digital Beamforming
3.6.2 Hybrid Beamforming
3.7 5G MIMO Multiple Input/Multiple Output
3.8 Digital Signal Processing
3.9 Software Re-Programmability
3.10 Software Defined Radio
3.11 Smart Antennas Application Sectors
3.12 Smart Antennas in IoT
3.13 Machine Learning and Artificial Neural Network
4. 5G Smart Antenna Market Dynamics
4.1 5G Smart Antenna Market Drivers
4.2 5G Smart Antenna Market Challenges
4.3 5G Smart Antenna Solution Considerations
4.4 5G Smart Antenna Use Case Analysis
4.4.1 Voice over 5G
4.4.2 Mission Critical Communications
4.4.3 Industrial Automation and Robotics
4.4.4 Connected and Self-Driving Vehicles
4.4.5 Drones and Unmanned Aerial Vehicles
5. 5G Smart Antenna Ecosystem Analysis
5.1 Ericsson
5.1.1 Overview
5.1.2 Recent Development
5.2 Cobham Antenna Systems
5.2.1 Overview
5.2.2 Recent Developments
5.3 Intel Corporation
5.3.1 Overview
5.3.2 Recent Developments
5.4 Samsung Electronics Co. Ltd.
5.4.1 Overview
5.4.2 Recent Developments
5.5 ArrayComm LLC
5.5.1 Overview
5.5.2 Recent Developments
5.6 Nokia Corporation
5.6.1 Overview
5.6.2 Recent Developments
5.7 Motorola Solutions Inc.
5.7.1 Overview
5.8 Broadcom Inc.
5.8.1 Overview
5.9 California Amplifier Inc.
5.9.1 Overview
5.10 Sierra Wireless (Accel Networks)
5.10.1 Overview
5.10.2 Recent Developments
5.11 ZHEJIANG JC Antenna Co. Ltd.
5.11.1 Overview
5.12 Qualcomm Incorporated
5.12.1 Overview
5.12.2 Recent Developments
5.13 Honeywell International Inc.
5.13.1 Overview
5.14 Linx Technologies
5.14.1 Overview
5.14.2 Recent Developments
5.15 Ruckus Networks
5.15.1 Overview
5.15.2 Recent Developments
5.16 ANSYS Inc.
5.16.1 Overview
5.17 Smart Antenna Technologies Ltd
5.17.1 Overview
5.18 NXP Semiconductors
5.18.1 Overview
5.18.2 Recent Developments
5.19 NEC Corporation
5.19.1 Overview
5.19.2 Recent Developments
5.20 COMMSCOPE
5.20.1 Overview
5.20.2 Recent Developments
5.21 PCTEL Inc.
5.21.1 Overview
5.21.2 Recent Developments
5.22 Comba Telecom
5.22.1 Overview
5.22.2 Recent Developments
5.23 Airgain Inc.
5.23.1 Overview
5.23.2 Recent Developments
5.24 Laird Technologies
5.24.1 Overview
5.24.2 Recent Developments
5.25 MediaTek Inc.
5.25.1 Overview
5.25.2 Recent Developments
5.26 LOCOSYS Technology Inc.
5.26.1 Overview
5.27 Leica Geosystems AG
5.27.1 Overview
5.27.2 Recent Developments
6. 5G Smart Antenna Market Analysis and Forecasts
6.1 Global 5G Smart Antenna Market 2021 – 2026
6.1.1 Total 5G Smart Antenna Market 2021 – 2026
6.1.1.1 5G Smart Antenna Market by Type 2021 – 2026
6.1.2 5G Smart Antennas by Frequency Range 2021 – 2026
6.1.3 5G Smart Antennas by Network Type 2021 – 2026
6.1.4 5G Smart Antennas by Technology 2021 – 2026
6.1.5 5G Smart Antennas by Connectivity System 2021 – 2026
6.1.6 5G Smart Antenna Market by Application 2021 – 2026
6.1.7 AI Embedded 5G Smart Antenna Market 2021 – 2026
6.1.7.1 Embedded 5G Smart Antennas by AI Technology 2021 – 2026
6.1.8 5G Smart Antenna Market in IoT 2021 – 2026
6.1.8.1 5G Smart Antenna Market in IoT by Application 2021 – 2026
6.2 Regional 5G Smart Antenna Market 2021 – 2026
6.2.1 5G Smart Antenna Market by Region 2021 – 2026
6.2.2 North America 5G Smart Antenna Market by Type, Technology, Application, AI, IoT, and Leading Country
6.2.3 Europe 5G Smart Antenna Market by Type, Technology, Application, AI, IoT, and Leading Country
6.2.4 APAC 5G Smart Antenna Market by Type, Technology, Application, AI, IoT, and Leading Country
6.2.5 Latin America 5G Smart Antenna Market by Type, Technology, Application, AI, IoT, and Leading Country
6.2.6 Middle East and Africa 5G Smart Antenna Market by Type, Technology, Application, AI, IoT, and Leading Country
7. Conclusions and Recommendations
Figures
Figure 1: Smart Antenna Architecture
Figure 2: 5G Directive High Gain Antenna
Figure 3: SIMO, MISO, and MIMO Architecture
Figure 4: Global Smart Antenna Unit Shipment 2021 – 2026
Figure 5: Smart Antenna Unit Shipment Percent by Price Range 2021 – 2026
Figure 6: Smart Antenna Unit Shipment Percent by Region 2021 – 2026
Figure 7: ArrayComm A-MAS Architecture
Figure 8: Nokia Antenna Solution Partner Ecosystem
Figure 9: D-SAS Control Function and Radio Resource Management Function
Figure 10: SmarTenna Architecture
Figure 11: Global Total 5G Smart Antenna Market 2021 – 2026
Figure 12: Global AI Embedded 5G Smart Antenna Market 2021 – 2026
Figure 13: Global 5G Smart Antenna Market in IoT 2021 – 2026
Figure 14: North America AI Embedded 5G Smart Antenna Market 2021 – 2026
Figure 15: North America 5G Smart Antenna Market in IoT 2021 – 2026
Figure 16: Europe AI Embedded 5G Smart Antenna Market 2021 – 2026
Figure 17: Europe 5G Smart Antenna Market in IoT 2021 – 2026
Figure 18: APAC AI Embedded 5G Smart Antenna Market 2021 – 2026
Figure 19: APAC 5G Smart Antenna Market in IoT 2021 – 2026
Figure 20: Latin America AI Embedded 5G Smart Antenna Market 2021 – 2026
Figure 21: Latin America 5G Smart Antenna Market in IoT 2021 – 2026
Figure 22: MEA AI Embedded 5G Smart Antenna Market 2021 – 2026
Figure 23: MEA 5G Smart Antenna Market in IoT 2021 – 2026
Tables
Table 1: Global 5G Smart Antenna by Segment 2021 – 2026
Table 2: Global 5G Smart Antennas by Frequency Range 2021 – 2026
Table 3: Global 5G Smart Antennas by Network Type 2021 – 2026
Table 4: Global 5G Smart Antennas by Technology 2021 – 2026
Table 5: Global 5G Smart Antenna Market by Connectivity System 2021 – 2026
Table 6: Global 5G Smart Antenna Market by Application 2021 – 2026
Table 7: Global AI Embedded 5G Smart Antenna Market by AI Technology 2021 – 2026
Table 8: Global 5G Smart Antenna Market in IoT by Application 2021 – 2026
Table 9: 5G Smart Antenna Market by Region 2021 – 2026
Table 10: North America 5G Smart Antenna by Segment 2021 – 2026
Table 11: North America 5G Smart Antenna by Technology 2021 – 2026
Table 12: North America 5G Smart Antenna Market by Connectivity System 2021 – 2026
Table 13: North America 5G Smart Antenna Market by Application 2021 – 2026
Table 14: North America AI Embedded 5G Smart Antenna Market by AI Technology 2021 – 2026
Table 15: North America 5G Smart Antenna Market in IoT by Application 2021 – 2026
Table 16: North America 5G Smart Antenna Market by Leading Country 2021 – 2026
Table 17: Europe 5G Smart Antenna by Segment 2021 – 2026
Table 18: Europe 5G Smart Antenna by Technology 2021 – 2026
Table 19: Europe 5G Smart Antenna Market by Connectivity System 2021 – 2026
Table 20: Europe 5G Smart Antenna Market by Application 2021 – 2026
Table 21: Europe AI Embedded 5G Smart Antenna Market by AI Technology 2021 – 2026
Table 22: Europe 5G Smart Antenna Market in IoT by Application 2021 – 2026
Table 23: Europe 5G Smart Antenna Market by Leading Country 2021 – 2026
Table 24: APAC 5G Smart Antenna by Segment 2021 – 2026
Table 25: APAC 5G Smart Antenna by Technology 2021 – 2026
Table 26: APAC 5G Smart Antenna Market by Connectivity System 2021 – 2026
Table 27: APAC 5G Smart Antenna Market by Application 2021 – 2026
Table 28: APAC AI Embedded 5G Smart Antenna Market by AI Technology 2021 – 2026
Table 29: APAC 5G Smart Antenna Market in IoT by Application 2021 – 2026
Table 30: APAC 5G Smart Antenna Market by Leading Country 2021 – 2026
Table 31: Latin America 5G Smart Antenna by Segment 2021 – 2026
Table 32: Latin America 5G Smart Antenna by Technology 2021 – 2026
Table 33: Latin America 5G Smart Antenna Market by Connectivity System 2021 – 2026
Table 34: Latin America 5G Smart Antenna Market by Application 2021 – 2026
Table 35: Latin America AI Embedded 5G Smart Antenna Market by AI Technology 2021 – 2026
Table 36: Latin America 5G Smart Antenna Market in IoT by Application 2021 – 2026
Table 37: Latin America 5G Smart Antenna Market by Leading Country 2021 – 2026
Table 38: MEA 5G Smart Antenna by Segment 2021 – 2026
Table 39: MEA 5G Smart Antenna by Technology 2021 – 2026
Table 40: MEA 5G Smart Antenna Market by Connectivity System 2021 – 2026
Table 41: MEA 5G Smart Antenna Market by Application 2021 – 2026
Table 42: MEA AI Embedded 5G Smart Antenna Market by AI Technology 2021 – 2026
Table 43: MEA 5G Smart Antenna Market in IoT by Application 2021 – 2026
Table 44: MEA 5G Smart Antenna Market by Leading Country 2021 – 2026
Distributed Antenna System Market by Technology, Type (Active, Passive, Hybrid), Coverage (Outdoor and Indoor), Operator (Carrier, Enterprise, Neutral Host) and Industry Vertical 2021 – 2026
1.0 Executive Summary
2.0 Introduction to Distributed Antenna Systems
2.1 DAS Role in Wireless Network Infrastructure
2.1.1 DAS Benefits to Mobile Network Operators
2.1.1.1 Improved Coverage and Quality of Service
2.1.1.2 Increased Capacity
2.1.1.3 Capital Cost Reduction
2.1.1.4 Speed to Market
2.1.2 DAS Deployment and Operational Challenges
2.2 DAS Technology
2.2.1 DAS Operations
2.2.1.1 Active, Passive, and Hybrid DAS
2.2.1.2 DAS Signal Controllers
2.2.1.3 Multi-Signal Combiner Systems
2.2.2 DAS and Small Cell Technology
2.2.2.1 Microcell Solutions
2.2.2.2 Pico/Metrocell Solutions
2.2.2.3 Femtocell Solutions
2.2.2.4 WiFi
2.2.2.5 Small Cell Capacity
2.2.2.6 Small Cell Cost vs. DAS
2.2.3 DAS and Self Organizing Networks
2.2.3.1 DAS and SON Coordinated Coverage and Quality
2.2.3.2 Beyond SON and DAS for Optimized Networks
3.0 DAS Ecosystem
3.1 DAS Ecosystem
3.1.1 DAS OEMs
3.1.1.1 Key Players
3.1.1.1.1 SOLiD
3.1.1.1.1.1 Business Overview
3.1.1.1.1.2 Services
3.1.1.1.2 Microlab, FX
3.1.1.1.2.1 Business Overview
3.1.1.1.2.2 Services
3.1.1.1.3 Andrew
3.1.1.1.4 Tyco (TE Connectivity)
3.1.1.1.5 Corning
3.1.1.1.5.1 Business Overview
3.1.1.1.5.2 Services
3.1.1.1.6 Dali Wireless
3.1.1.1.6.1 Business Overview
3.1.1.1.6.2 Services
3.1.2 Wireless Service Providers
3.1.2.1 Key Players
3.1.2.1.1 Boingo Wireless
3.1.2.1.1.1 Business Overview
3.1.2.1.1.2 Services
3.1.2.1.2 China Mobile
3.1.2.1.2.1 Business Overview
3.1.2.1.2.2 Services
3.1.3 Distribution
3.1.4 Cable Contractors
3.1.4.1 Key Players
3.1.4.1.1 DAS Simplified
3.1.4.1.1.1 Business Overview
3.1.4.1.1.2 Services
3.1.5 DAS Integrator
3.1.5.1 Key Players
3.1.5.1.1 AT&T’s Antenna Solutions Group (ASG)
3.1.5.1.1.1 Business Overview
3.1.5.1.1.2 Services
3.1.5.1.2 American Tower Corporation
3.1.5.1.2.1 Business Overview
3.1.5.1.2.2 Services
3.1.5.1.3 Axell
3.1.5.1.3.1 Business Overview
3.1.5.1.3.2 Services
3.1.6 End-User Customers
3.2 DAS Deployment and Operational Challenges
3.2.1 Regulatory Issues
3.2.1.1 DAS Regulations
3.2.1.2 Vagueness of Current Legislation
3.2.2 Deployment Issues
3.2.3 Technical Issues
3.2.3.1 DAS Multiple Service Offerings
3.2.3.2 Supporting Future Requirements
3.3 DAS Market Dynamics
3.3.1 Drivers
3.3.1.1 High Data Traffic
3.3.1.2 High Proliferation of Connected Devices in Internet of Things (IoT)
3.3.1.3 Growth for Public Safety Connectivity
3.3.2 Challenges
3.3.2.1 High Complexity
3.3.2.2 High Cost
3.3.3 Key DAS Case Studies
3.3.3.1 VicTrack Rolled Out P25 Digital Distributed Antenna System
3.3.3.1.1 Background
3.3.3.1.2 Solution
3.3.3.2 Digital Distributed Antenna System in Hospital
3.3.3.3 Cellular Distributed Antenna Systems for Skanska USA Building
3.3.3.4 Distributed Antenna System at the Minnesota State Fair
3.3.3.5 Torre Diamante Building Case Study
3.3.3.6 Tottenham Hotspur Case Study
3.3.3.7 Axel Towers Case Study
3.3.3.8 W New York Times Square, NYC Case Study
3.3.4 5G and DAS
3.3.4.1 Passive DAS
3.3.4.2 Active DAS
3.3.4.3 Small Cell
3.3.4.4 Adaptive Beamforming
4.0 DAS Companies and Solutions
4.1 Enterprise Connectivity
4.1.1 Key Players
4.1.1.1 iBwave
4.1.1.1.1 Business Overview
4.1.1.1.2 Services
4.1.1.1.3 Recent Developments
4.1.1.2 TCS
4.1.1.2.1 Business Overview
4.1.1.2.2 Services
4.1.1.2.3 Recent Developments
4.2 Public Safety
4.2.1 Key Players
4.2.1.1 Crown Castle
4.2.1.1.1 Business Overview
4.2.1.1.2 Services
4.2.1.1.3 Recent Developments
4.3 Healthcare
4.3.1 Key Players
4.3.1.1 Alcatel-Lucent Enterprise
4.3.1.1.1 Business Overview
4.3.1.1.2 Services
4.3.1.1.3 Recent Developments
4.3.1.2 Legrand
4.3.1.2.1 Business Overview
4.3.1.2.2 Services
4.4 Transportation
4.4.1 Railways
4.4.1.1 Key Players
4.4.1.1.1 CommScope
4.4.1.1.1.1 Business Overview
4.4.1.1.1.2 Services
4.4.1.1.1.3 Recent Developments
4.4.1.1.2 InSite Wireless
4.4.1.1.2.1 Business Overview
4.4.1.1.2.2 Services
4.4.1.1.2.3 Recent Developments
4.4.2 Airports
4.4.2.1 Key Players
4.4.2.1.1 TE Connectivity
4.4.2.1.1.1 Business Overview
4.4.2.1.1.2 Services
4.4.2.1.1.3 Recent Developments
4.4.3 Street Stations
4.4.3.1 Key Players
4.4.3.1.1 iWireless
4.4.3.1.1.1 Business Overview
4.4.3.1.1.2 Services
4.5 Sports
4.5.1 Key Players
4.5.1.1 Essentia
4.5.1.1.1 Business Overview
4.5.1.1.2 Services
4.5.1.2 Optical Telecom
4.5.1.2.1 Business Overview
4.5.1.2.2 Services
4.5.1.2.3 Recent Developments
4.5.1.3 FoxCom
4.5.1.3.1 Business Overview
4.5.1.3.2 Services
4.5.1.4 Westell
4.5.1.4.1 Business Overview
4.5.1.4.2 Services
4.5.1.5 Comba Telecom Systems Holding
4.5.1.5.1 Business Overview
4.5.1.5.2 Services
4.5.1.5.3 Recent Developments
4.6 Entertainment
4.6.1 Key Players
4.6.1.1 Crown Castle
4.6.1.1.1 Business Overview
4.6.1.1.2 Services
4.6.1.1.3 Recent Developments
5.0 DAS Market Analysis and Forecasts 2021 – 2026
5.1 Combined DAS Market 2021 – 2026
5.1.1 Combined DAS Market Revenue
5.1.2 DAS Market by Equipment, Applications, and Services
5.1.3 DAS Revenue by Indoor and Outdoor Environments
5.1.4 DAS Revenue by Indoor DAS Type
5.1.5 DAS Revenue by Ownership
5.1.6 DAS Revenue by Industry Verticals
5.1.7 DAS Revenue by Technology
5.1.8 DAS Revenue by Region
5.1.8.1 Revenue by North America Country
5.1.8.2 Revenue by Asia Pacific Country
5.1.8.3 Revenue by Europe Country
5.1.8.4 Revenue by Middle East & Africa Country
5.1.8.5 Revenue by Latin America Country
5.2 DAS Equipment Market 2021 – 2026
5.2.1 DAS Equipment Market by Indoor and Outdoor Environments
5.2.2 DAS Indoor Equipment Market
5.2.3 DAS Equipment Market by Carrier, Enterprise and Neutral Host Deployment
5.2.4 DAS Equipment Market by Industry Verticals
5.2.5 DAS Equipment Market by Technology
5.2.6 DAS Equipment Market by Region
5.2.6.1 DAS Market by North America Country
5.2.6.2 DAS Market by Asia Pacific Country
5.2.6.3 DAS Market by Europe Country
5.2.6.4 DAS Market by Middle East & Africa Country
5.2.6.5 DAS Market by Latin America Country
5.3 DAS Application Market 2021 – 2026
5.3.1 DAS Application Market by Indoor and Outdoor Environments
5.3.2 Indoor DAS Deployment by Active, Passive and Hybrid
5.3.3 DAS Application Market by Carrier, Enterprise, and Neutral Host Deployment
5.3.4 DAS Application Market by Industry Verticals
5.3.5 DAS Application Market by Technology
5.3.6 DAS Application Market by Region
5.3.6.1 DAS Market by North America Country
5.3.6.2 DAS Market by Asia Pacific Country
5.3.6.3 DAS Market by Europe Country
5.3.6.4 DAS Market by Middle East & Africa Country
5.3.6.5 DAS Market by Latin America Country
5.4 DAS Service Market 2021 – 2026
5.4.1 DAS Market by Indoor and Outdoor Environments
5.4.2 Indoor DAS Service Market
5.4.3 DAS Service Market by Carrier, Enterprise, and Neutral Host Environments
5.4.4 DAS Service Market by Vertical Industry
5.4.5 DAS Service Market by Technology
5.4.6 DAS Service Market by Region
5.4.6.1 DAS Market by North America Country
5.4.6.2 DAS Market by Asia Pacific Country
5.4.6.3 Market by Europe Country
5.4.6.4 Market by Middle East & Africa Country
5.4.6.5 Market by Latin America Country
5.5 DAS System Deployment 2021 – 2026
5.5.1 DAS System Deployment Unit
5.5.2 DAS Units by Indoor and Outdoor Environments
5.5.3 Indoor DAS Unit Deployments
5.5.4 DAS Units by Carrier, Enterprise and Neutral Host Deployment
5.5.5 DAS Units by Industry Verticals
5.5.6 DAS Units by Technology
5.5.7 DAS Units by Region
5.5.7.1 Unit by North America Country
5.5.7.2 Unit by Asia Pacific Country
5.5.7.3 Unit by Europe Country
5.5.7.4 Unit by Middle East & Africa Country
5.5.7.5 Unit by Latin America Country
5.6 Global 5G Smart Antennas DAS Market 2021 – 2026
5.6.1 Global 5G DAS (Smart Antenna) Market
5.6.2 5G Smart Antenna DAS Market by Type
5.6.3 5G Smart Antenna DAS Market by Technology
5.6.4 5G Smart Antenna DAS Market by Connectivity
5.6.5 5G Smart Antenna DAS Market by Frequency
5.6.6 5G Smart Antenna DAS Market by Application
5.6.7 Global AI Embedded 5G Smart Antenna DAS Market
5.6.7.1 5G Smart Antenna DAS Market by AI Technology
5.6.8 5G Smart Antenna DAS Market by Region
5.6.8.1 North America Market by Country
5.6.8.2 Asia Pacific Market by Country
5.6.8.3 Europe Market by Country
5.6.8.4 Middle East & Africa Market by Country
5.6.8.5 Latin America Market by Country
5.7 Distributed Antenna System Structure
5.8 Distributed Antenna System Deployment Costs
5.9 Distributed Antenna System Life Cycle
5.10 Distributed Antenna System Quality Metrics
5.10.1 Distributed Antenna System Deployment Challenges
5.10.2 Distributed Antenna System Deployment Barriers
5.10.3 Distributed Antenna System Proposal Metrics
6.0 Conclusions and Recommendations
Figures
Figure 1: In-Building Coverage with DAS
Figure 2: Outdoor DAS Coverage
Figure 3: DAS Signal Controllers
Figure 4: DAS Network Topology
Figure 5: CPRI Connected Small Cells
Figure 6: Micro Cell Coverage
Figure 7: Femto/Pico Cell Architecture
Figure 8: DAS vs. Small Cells in Different Buildings
Figure 9: SON Capabilities
Figure 10: SON Business Drivers
Figure 11: SON Architecture
Figure 12: DAS Drivers and Challenges
Figure 13: Adaptive Beamforming System
Figure 14: Global DAS Market 2021 – 2026
Figure 15: Global 5G Smart Antenna DAS Market 2021 – 2026
Figure 16: Global AI Embedded 5G Smart Antenna DAS Market 2021 – 2026
Tables
Table 1: iBwave Partnership
Table 2: TCS Partnership
Table 3: Crowne Castle Partnership
Table 4: Alcatel-Lucent Enterprise Partnership
Table 5: CommScopePartnership
Table 6: InSite Wireless Partnership
Table 7: TE ConnectivityPartnership
Table 8: Optical TelecomPartnership
Table 9: Comba TelecomPartnership
Table 10: Global DAS Market by Equipment, Applications and Services 2021 – 2026
Table 11: Global DAS Revenue by Coverage Type 2021 – 2026
Table 12: Global Indoor DAS Revenue by Type 2021 – 2026
Table 13: Global DAS Revenue by Ownership Type 2021 – 2026
Table 14: Global DAS Revenue by Vertical Industry 2021 – 2026
Table 15: Global DAS Revenue by Supporting Technology 2021 – 2026
Table 16: Global DAS Revenue by Region 2021 – 2026
Table 17: North America DAS Revenue by Country 2021 – 2026
Table 18: Asia Pacific DAS Revenue by Country 2021 – 2026
Table 19: Europe DAS Revenue by Country 2021 – 2026
Table 20: Middle East & Africa DAS Revenue by Country 2021 – 2026
Table 21: Latin America DAS Revenue by Country 2021 – 2026
Table 22: Global DAS Equipment Revenue by Coverage Type 2021 – 2026
Table 23: Global Indoor DAS Equipment by Revenue Type 2021 – 2026
Table 24: Global DAS Equipment Revenue by Ownership Type 2021 – 2026
Table 25: Global DAS Equipment Revenue by Vertical Industry 2021 – 2026
Table 26: Global DAS Equipment Revenue by Supporting Technology 2021 – 2026
Table 27: Global DAS Equipment Revenue by Region 2021 – 2026
Table 28: North America DAS Equipment Revenue by Country 2021 – 2026
Table 29: Asia Pacific DAS Equipment Revenue by Country 2021 – 2026
Table 30: Europe DAS Equipment Revenue by Country 2021 – 2026
Table 31: Middle East & Africa DAS Equipment Revenue by Country 2021 – 2026
Table 32: Latin America DAS Equipment Revenue by Country 2021 – 2026
Table 33: Global DAS Application Revenue by Indoor and Outdoor Environments 2021 – 2026
Table 34: Global Indoor DAS by Active, Passive and Hybrid 2021 – 2026
Table 35: Global DAS by Carrier vs. Enterprise vs. Neutral Hosts 2021 – 2026
Table 36: Global DAS Application Revenue by Vertical Industry 2021 – 2026
Table 37: Global DAS Application Revenue by Supporting Technology 2021 – 2026
Table 38: Global DAS Application Revenue by Region 2021 – 2026
Table 39: North America DAS Application Revenue by Country 2021 – 2026
Table 40: Asia Pacific DAS Application Revenue by Country 2021 – 2026
Table 41: Europe DAS Application Revenue by Country 2021 – 2026
Table 42: Middle East & Africa DAS Application Revenue by Country 2021 – 2026
Table 43: Latin America DAS Application Revenue by Country 2021 – 2026
Table 44: Global DAS Service Revenue by Coverage Type 2021 – 2026
Table 45: Global Indoor DAS Service Revenue by Type 2021 – 2026
Table 46: Global DAS Service Revenue by Ownership Type 2021 – 2026
Table 47: Global DAS Service Revenue by Vertical Industry 2021 – 2026
Table 48: Global DAS Service Revenue by Supporting Technology 2021 – 2026
Table 49: Global DAS Service Revenue by Region 2021 – 2026
Table 50: North America DAS Service Revenue by Country 2021 – 2026
Table 51: Asia Pacific DAS Service Revenue by Country 2021 – 2026
Table 52: Europe DAS Service Revenue by Country 2021 – 2026
Table 53: Middle East & Africa DAS Service Revenue by Country 2021 – 2026
Table 54: Latin America DAS Service Revenue by Country 2021 – 2026
Table 55: Global DAS System Deployment by Coverage Type 2021 – 2026
Table 56: Global Indoor DAS System Deployment by Type 2021 – 2026
Table 57: Global DAS System Deployment by Ownership Type 2021 – 2026
Table 58: Global DAS System Deployment by Vertical Industry 2021 – 2026
Table 59: Global DAS System Deployment by Supporting Technology 2021 – 2026
Table 60: Global DAS System Deployment by Region 2021 – 2026
Table 61: North America DAS System Deployment Unit by Country 2021 – 2026
Table 62: Asia Pacific DAS System Deployment by Country 2021 – 2026
Table 63: Europe DAS System Deployment by Country 2021 – 2026
Table 64: Middle East & Africa DAS System Deployment by Country 2021 – 2026
Table 65: Latin America DAS System Deployment by Country 2021 – 2026
Table 66: Global 5G Smart Antenna DAS Market by Type 2021 – 2026
Table 67: Global 5G Smart Antenna DAS Market by Technology 2021 – 2026
Table 68: Global 5G Smart Antenna DAS Market by Connectivity 2021 – 2026
Table 69: Global 5G Smart Antenna DAS Market by Frequency 2021 – 2026
Table 70: Global 5G Smart Antenna DAS Market by Application 2021 – 2026
Table 71: Global AI Embedded 5G Smart Antenna DAS Market by AI Technology 2021 – 2026
Table 72: Global 5G Smart Antenna DAS Market by Region 2021 – 2026
Table 73: North America 5G Smart Antenna DAS Market by Country 2021 – 2026
Table 74: Asia Pacific 5G Smart Antenna DAS Market by Country 2021 – 2026
Table 75: Europe 5G Smart Antenna DAS Market by Country 2021 – 2026
Table 76: Middle East & Africa 5G Smart Antenna DAS Market by Country 2021 – 2026
Table 77: Latin America 5G Smart Antenna DAS Market by Country 2021 – 2026
Table 78: Indoor vs. Outdoor DAS Structure
Table 79: Deployment Costs of DAS System
Table 80: DAS System Deployment Life Cycle
Table 81: DAS System Deployment Challenges by Users
Table 82: DAS System Deployment Barriers by Users
Table 83: DAS System Proposal Metrics by Users
5G Network Densification Market by Location (Indoor & Outdoor), Spectrum Band, Small Cells and Carrier WiFi 2021 – 2026
1 Executive Summary
2 Carrier WiFi and Small Cell Technology
2.1 Evolution towards Heterogeneous Networks
2.2 Carrier WiFi
2.2.1 Open Access vs. Mobile Data Offload Carrier WiFi
2.2.2 Convergence with Small Cell Solutions
2.3 Small Cells
2.3.1 Femtocells
2.3.2 Picocells
2.3.3 Microcells
2.3.4 Metrocells
2.4 Convergent Small Cell Architecture
2.5 Small Cell Deployment Scenarios
2.5.1 Home/Residential Deployments:
2.5.2 Enterprise Deployments:
2.5.3 Metro and Public Space Deployments:
2.5.4 Rural Deployments:
2.6 Carrier WiFi and Small Cell Standardization
2.6.1 Small Cell Forum
2.6.2 Hotspot Task Group
2.6.3 Next Generation Hotspot
3 5G Network Planning and Densification
3.1 Overview
3.2 Small Cells and 5G Future
3.3 Top Ten Milestones on the Road to 5G
3.4 Plans and Initiatives of 5G by Government
3.5 Creation of a Diverse Telecoms Supply Market
3.6 Use Cases Associated with 5G
4 Business Case for the Carrier WiFi and Small Cells
4.1 Key Market Drivers
4.1.1 The Increasing Demand for Mobile Broadband
4.1.2 CapEX and OpEX Reduction
4.1.3 Licensed RF frequencies
4.1.4 Support for Various Wireless Technologies/Environments
4.1.5 Higher Throughput per Cell
4.1.6 Quality of Service
4.1.7 Energy Savings: Towards a Greener Network Environment
4.1.8 New Application and Service Opportunities
4.1.9 Small Cell Targeted Advertising
4.2 Market Barriers and Challenges
4.2.1 Coverage and Performance Uncertainty
4.2.2 Security Considerations
4.2.3 Interference Management
4.2.4 Mobility Management
4.2.5 Self-Organization
4.2.6 Backhaul Challenges
4.2.7 Alternative Solutions
4.3 Carrier WiFi and Small Cells Value Chain
4.4 Carrier WiFi and Small Cell Industry Roadmap
4.4.1 Commercialization of Femtocells
4.4.2 Managed WiFi Data Offloading
4.4.3 Macrocells, Small Cells and Carrier WiFi Integration
4.5 Carrier WiFi and Small Cells in LTE and Beyond: Key Trends
4.5.1 Distributed Antenna System Integration
4.5.2 Small Cells as a Service (SCaaS) and Femtocells as a Service (FaaS)
4.5.3 Self-Organizing Networks (SON)
4.5.4 Cloud RAN and its Impact on the Small Cell Industry
4.5.5 Proliferation of WiFi Technology in Small Cells
5 Major Carrier WiFi and Small Cell Deployments
5.1 AT&T Mobility
5.1.1 Company Overview
5.1.2 5G Network Densification of Company
5.2 Eircom
5.2.1 Company Overview
5.2.2 5G Network Densification of Company
5.3 KDDI
5.3.1 Company Overview
5.3.2 5G Network Densification of Company
5.4 Korea Telecom
5.4.1 Company Overview
5.4.2 5G Network Densification of Company
5.5 SK Telecom
5.5.1 Company Overview
5.5.2 5G Network Densification of Company
5.6 Optus Australia
5.6.1 Company Overview
5.6.2 5G Network Densification of Company
5.7 SFR France
5.7.1 Company Overview
5.7.2 5G Network Densification of Company
5.8 Sprint (T-Mobile)
5.8.1 Company Overview
5.8.2 5G Network Densification of Company
5.9 Reliance Communications
5.9.1 Company Overview
5.9.2 5G Network Densification of Company
5.10 Softbank Japan
5.10.1 Company Overview
5.10.2 5G Network Densification of Company
5.11 NTT DoCoMo
5.11.1 Company Overview
5.11.2 5G Network Densification of Company
5.12 SingTel
5.12.1 Company Overview
5.12.2 5G Network Densification of Company
5.13 Telefonica O2 UK
5.13.1 Company Overview
5.13.1 5G Network Densification of Company
5.14 T-Mobile
5.14.1 Company Overview
5.14.2 5G Network Densification of Company
5.15 Tim Brasil
5.15.1 Company Overview
5.15.2 5G Network Densification of Company
5.16 US Cellular
5.16.1 Company Overview
5.16.2 5G Network Densification of Company
5.17 Verizon Wireless
5.17.1 Company Overview
5.17.2 5G Network Densification of Company
5.18 Vodafone
5.18.1 Company Overview
5.18.2 5G Network Densification of Company
5.19 China Mobile
5.19.1 Company Overview
5.19.2 5G Network Densification of Company
5.20 Comcast
5.20.1 Company Overview
5.20.2 5G Network Densification of Company
5.21 Zain Bahrain
5.21.1 Company Overview
5.21.2 5G Network Densification of Company
5.22 Zain Saudi Arabia
5.22.1 Company Overview
5.22.2 5G Network Densification of Company
6 Vendor Landscape
6.1 Key Vendor Strategic Initiatives in 5G Network Densification
6.2 Vendor Product Portfolio and Strategy
6.2.1 ADTRAN
6.2.2 Argela
6.2.3 Airvana
6.2.4 Aptilo Networks
6.2.5 Arcadyan Technology Corporation
6.2.6 Aruba Networks
6.2.7 Alcatel-Lucent Enterprise
6.2.8 Aviat Networks
6.2.9 Cisco
6.2.10 CommScope
6.2.11 Contela
6.2.12 Ericsson
6.2.13 Huawei
6.2.14 ip.access
6.2.15 Juniper Networks
6.2.16 Motorola Solutions
6.2.17 NEC
6.2.18 Radisys
6.2.19 Samsung
7 Strategies for Deployment and Operations
7.1 Network Planning and Dimensioning
7.2 Small Cell AP Type
7.3 Interference Management
7.4 Auto-configuration and SON
7.5 Carrier Aggregation
7.6 Seamless Mobility
7.7 Authentication and Security
7.8 Backhaul Solutions
7.9 Upgradability
7.10 Target Site Selection
7.11 Requirements Specification and Procurement
7.12 CapEx, OpEx, and TCO
8 5G Network Densification Market Analysis and Forecasts
8.1 Global Carrier WiFi Market 2021 – 2026
8.1.1 Global Carrier WiFi Unit Shipments and Revenue 2021 – 2026
8.1.2 Global Carrier WiFi Access Point and Controller Unit Shipments 2021 – 2026
8.1.3 WiFi Offload vs. Standard WiFi Access Points 2021 – 2026
8.1.4 Regional Carrier WiFi Market 2021 – 2026
8.2 Carrier WiFi Unit Shipments and Revenues by Region 2021 – 2026
8.2.1 Asia Pacific
8.2.2 Eastern Europe
8.2.3 Latin & Central America
8.2.4 Middle East & Africa
8.2.5 North America
8.2.6 Western Europe
8.3 Global Small Cell Market 2021 – 2026
8.3.1 Global Small Cell Unit Shipments and Revenue 2021 – 2026
8.3.2 Global Small Cell Unit Shipments and Revenue by Cell Type: 2021 – 2026
8.3.3 Global Femtocell Unit Shipments and Revenue 2021 – 2026
8.3.4 Global Picocell Unit Shipments and Revenue 2021 – 2026
8.3.5 Global Microcell Unit Shipments and Revenue 2021 – 2026
8.3.6 Global Small Cell Unit Shipments and Revenue by Technology 2021 – 2026
8.3.7 Global Small Cell Unit Shipments by Spectrum 2021 – 2026
8.3.8 Global 5G Small Cell Unit Shipments and Revenue by Location 2021 – 2026
8.3.9 Global 5G Small Cell Unit Shipments by Technology 2021 – 2026
8.3.10 Regional Small Cell Market 2021 – 2026
8.4 Small Cell Unit Shipments and Revenues by Region 2021 – 2026
8.4.1 Asia Pacific
8.4.2 Eastern Europe
8.4.3 Latin and Central America
8.4.4 Middle East and Africa
8.4.5 North America
8.4.6 Western Europe
Figures
Figure 1: HetNet Ecosystem
Figure 2: Mobile Data Offloading via WiFi within a Carrier Network
Figure 3: Small Cell Deployments within a Carrier Network
Figure 4: Small Cell Deployments in Home, Enterprise, Urban and Rural Scenarios
Figure 5: Small Cell Scope
Figure 6: The Carrier WiFi and Small Cells Value Chain
Figure 7: Carrier WiFi and Small Cells Industry Roadmap
Figure 8: Self Organizing Networks
Figure 9: KDDI’s 3M Vision and Strategy
Figure 10: Carrier WiFi Unit Shipments 2021 – 2026
Figure 11: Carrier WiFi Unit Revenues 2021 – 2026
Figure 12: Carrier WiFi Unit Shipments by Category 2021 – 2026
Figure 13: Carrier WiFi Unit Shipment Revenues by Category 2021 – 2026
Figure 14: WiFi Offload vs. Standard WiFi Access Point Unit Shipments 2021 – 2026
Figure 15: Carrier WiFi Offload Access Point Unit Shipments 2021 – 2026
Figure 16: Standard Carrier WiFi Access Point Unit Shipments 2021 – 2026
Figure 17: WiFi Offload vs. Standard WiFi Access Point Unit Shipment Revenues 2021 – 2026
Figure 18: Carrier WiFi Offload Access Point Unit Shipment Revenues 2021 – 2026
Figure 19: Standard Carrier WiFi Access Point Unit Shipment Revenues 2021 – 2026
Figure 20: Carrier WiFi Unit Shipments by Region 2021 – 2026
Figure 21: Carrier WiFi Revenues by Region 2021 – 2026
Figure 22: Carrier WiFi Unit Shipments in Asia Pacific 2021 – 2026
Figure 23: Carrier WiFi Revenues in Asia Pacific 2021 – 2026
Figure 24: Carrier WiFi Unit Shipments in Eastern Europe 2021 – 2026
Figure 25: Carrier WiFi Revenues in Eastern Europe 2021 – 2026
Figure 26: Carrier WiFi Unit Shipments in Latin & Central America 2021 – 2026
Figure 27: Carrier WiFi Revenues in Latin & Central America 2021 – 2026
Figure 28: Carrier WiFi Unit Shipments in Middle East & Africa 2021 – 2026
Figure 29: Carrier WiFi Revenues in Middle East & Africa 2021 – 2026
Figure 30: Carrier WiFi Unit Shipments in North America 2021 – 2026
Figure 31: Carrier WiFi Revenues in North America 2021 – 2026
Figure 32: Carrier WiFi Unit Shipments in Western Europe 2021 – 2026
Figure 33: Carrier WiFi Revenues in Western Europe 2021 – 2026
Figure 34: Small Cell Unit Shipments 2021 – 2026
Figure 35: Small Cell Revenues 2021 – 2026
Figure 36: Small Cell Unit Shipments by Cell Type 2021 – 2026
Figure 37: Small Cell Revenues by Cell Type 2021 – 2026
Figure 38: Femtocell Unit Shipments 2021 – 2026
Figure 39: Femtocell Revenues 2021 – 2026
Figure 40: Picocell Unit Shipments 2021 – 2026
Figure 41: Picocell Revenues 2021 – 2026
Figure 42: Microcell Unit Shipments 2021 – 2026
Figure 43: Microcell Revenues 2021 – 2026
Figure 44: Small Cell Unit Shipments by Technology 2021 – 2026
Figure 45: Small Cell Revenues by Technology 2021 – 2026
Figure 46: Small Cell Unit Shipments by Spectrum 2021 – 2026
Figure 47: 5G Small Cell Unit Shipments by Location 2021 – 2026
Figure 48: 5G Small Cell Revenues by Location 2021 – 2026
Figure 49: 5G Small Cell Unit Shipments by Technology 2021 – 2026
Figure 50: Small Cell Unit Shipments by Region 2021 – 2026
Figure 51: Small Cell Revenues by Region 2021 – 2026
Figure 52: Small Cell Unit Shipments in Asia Pacific 2021 – 2026
Figure 53: Small Cell Revenues in Asia Pacific 2021 – 2026
Figure 54: Small Cell Unit Shipments in Eastern Europe 2021 – 2026
Figure 55: Small Cell Revenues in Eastern Europe 2021 – 2026
Figure 56: Small Cell Unit Shipments in Latin & Central America 2021 – 2026
Figure 57: Small Cell Revenues in Latin & Central America 2021 – 2026
Figure 58: Small Cell Unit Shipments in Middle East & Africa 2021 – 2026
Figure 59: Small Cell Revenues in Middle East & Africa 2021 – 2026
Figure 60: Small Cell Unit Shipments in North America 2021 – 2026
Figure 61: Small Cell Revenues in North America 2021 – 2026
Figure 62: Small Cell Unit Shipments in Western Europe 2021 – 2026
Figure 63: Small Cell Revenues in Western Europe 2021 – 2026
Tables
Table 1: Strategy Focus Areas for Deployment
Table 2: Small Cell Interference Types
Table 3: Interference Management Capabilities for Small Cells
Table 4: Core SON Capabilities
Table 5: Strategic Requirements and Drivers for SON
Table 6: SON Architecture Types
Table 7: SON Vendors, Products, and Solutions
Table 8: Carrier Aggregation Types
Table 9: Small Cell Mobility Feature Requirements
Table 10: Solutions for Seamless Mobility Support in Small Cells
Table 11: Vendor Solutions for Seamless Mobility
Table 12: Authentication and Security Requirements
Table 13: Security Solutions for Small Cell Networks
Table 14: Backhaul Feature Requirements
Table 15: Backhaul Solution Requirements and Options
Table 16: Strategy Focus Areas for Business Aspects
Table 17: Strategy for Target Site Selection
Table 18: Key Areas for Requirements Specification and Procurement Plan
Self Organizing Network Market by Technology, Infrastructure, Solutions, and Services 2021 – 2026
1.0 Executive Summary
2.0 SON Technology Overview
2.1 The Evolution towards Heterogeneous Networks
2.2 SON in 3GPP Release 11
2.2.1 Releases 8, 9 and 10 Standardization
2.2.2 3GPP Release 8
2.2.3 3GPP Release 9
2.2.4 3GPP release 10
2.2.5 3GPP Release 11
2.3 Self-Organizing Networks Overview
2.4 Self-Organizing Networks Benefits
2.4.1 Network Automation
2.4.2 Energy Saving
2.4.3 Lower Equipment Costs
2.4.4 Distributed/Self-Organizing (DSO)
2.4.5 Cooperative Relaying (CR) in SON
2.4.6 SON Feedback Overhead
2.4.7 Codebook-based Pre-coding SON
2.4.8 SON Feedback Delays
3.0 SON Use Cases and Market Status
3.1 SON Applications
3.1.1 Self-Configuration
3.1.2 Self-Optimization
3.1.3 Self-Healing
3.1.4 Problems with Self-Healing
3.2 Implementation and Operations Options
3.2.1 Centralized SON
3.2.2 Distrusted SON
3.2.3 Localized SON
3.2.4 Hybrid SON
3.3 SON Releases
3.4 Automatic Neighbor Relation
3.5 SON Load Balancing
3.6 Mobility Robustness Optimization
3.7 Distributed Clustering in SON
3.8 Operational Use Cases
3.9 ICIC Enhancement
3.10 Urban Self-Organizing Networks
3.10.1 Home/Residential Deployments:
3.10.2 Enterprise Deployments:
3.10.3 Metro and Public Space Deployments:
3.10.4 Rural Deployments:
3.10.5 SON and Small Cell Deployments
4.0 SON and Smart Antennas
4.1 Electrical Tilt
4.2 Mechanical Tilt
4.3 SON vs. SON-related Technologies/Solutions
4.4 Installing Antenna Tilt and its Parameters
4.5 Antenna Tilt Features and ROI
4.5.1 Overcoming Performance Issues in a Specific DAS Coverage Area
4.5.2 Energy Savings
5.0 SON Business Value
5.1 NGMN Use Case
5.2 Operators Benefits
5.3 Values of the SON to Operators
5.3.1 Economic Benefits
5.3.2 SON Implementation Expenditures
5.3.3 SON Capital Expenditures
5.3.4 SON Operational Expenditures
5.3.5 Smarter Self Organizing Networks
5.4 Recommendations for Operators to Deploy LTE
6.0 SON Vendor Landscape
6.1 Airhop Communications
6.2 Airspan
6.3 Amdocs
6.4 Ascom Holding AG
6.5 BLiNQ Networks
6.6 Bwtech
6.7 Casa Systems
6.8 Ccs (Cambridge Communication Systems) Ltd.
6.9 Cellwize Wireless Technologies Pte Ltd.
6.10 Cisco
6.11 Comarch
6.12 Commscope
6.13 Ericsson
6.14 Huawei Technologies Co., Ltd.
6.15 Mera
6.16 NEC
6.17 Nokia
6.18 P.I. Works
6.19 Qualcomm
6.20 RadiSys Corporation
6.21 Reverb Networks
6.22 Rohde & Schwarz
6.23 Siemens AG
6.24 Teoco Corporation
6.25 Verizon
6.26 Viavi Solutions
6.27 ZTE Corporation
7.0 Self Organizing Network Market Analysis and Forecasts
7.1 Global SON Market 2021 – 2026
7.2 SON Revenue by Platform Type 2021 – 2026
7.3 SON Revenue by Architecture Type 2021 – 2026
7.4 SON Revenue by Access Network Technology Type 2021 – 2026
7.5 SON Revenue by Network Segment Type 2021 – 2026
7.6 SON Revenue for RAN Optimization by Infrastructure 2021 – 2026
7.7 SON Revenue for Applications 2021 – 2026
7.8 SON Revenue by Service Type 2021 – 2026
7.8.1 SON Revenue by Professional Service Type 2021 – 2026
7.8.2 SON Revenue by Managed Service Type 2021 – 2026
7.9 Conventional Mobile Network Planning and Optimization Revenue 2021 – 2026
7.10 Conventional Mobile Network Planning and Optimization Revenue by Region 2021 – 2026
7.11 SON Revenue by Region 2021 – 2026
7.11.1 North America SON Revenue by Country 2021 – 2026
7.11.2 South America SON Revenue by Country 2021 – 2026
7.11.3 Europe SON Revenue by Country 2021 – 2026
7.11.4 APAC SON Revenue by Country 2021 – 2026
7.11.1 MEA SON Revenue by Country 2021 – 2026
Figures
Figure 1: HetNet Network Topology
Figure 2: SON Use Cases
Figure 3: LTE SON Releases
Figure 4: Centralized, Distributed and Localized SON Comparison
Figure 5: SON Operational Use Cases
Figure 6: Self Organizing Networks and Small Cells
Figure 7: Antenna Tilt
Figure 8: Electrical Tilt
Figure 9: Mechanical Tilt
Figure 10: SON Operational Efficiency
Figure 11: Fundamental SON Capabilities
Figure 12: Strategic Requirements and Business Drivers for SON
Figure 13: SON Architecture Configurations
Figure 14: Global SON Market 2021 – 2026
Figure 15: SON Revenue by Platform Type 2021 – 2026
Figure 16: SON Revenue by Architecture Type 2021 – 2026
Figure 17: SON Revenue by Access Network Technology Type 2021 – 2026
Figure 18: SON Revenue by Network Segment Type 2021 – 2026
Figure 19: SON Revenue for RAN Optimization by Infrastructure 2021 – 2026
Figure 20: SON Revenue for Applications 2021 – 2026
Figure 21: SON Revenue by Service Type 2021 – 2026
Figure 22: SON Revenue by Professional Service Type 2021 – 2026
Figure 23: SON Revenue by Managed Service Type 2021 – 2026
Figure 24: Conventional Mobile Network Planning & Optimization Revenue 2021 – 2026
Figure 25: Conventional Mobile Network Planning & Optimization Revenue by Region 2021 – 2026
Figure 26: SON Revenue by Region 2021 – 2026
Figure 27: North America SON Revenue by Country 2021 – 2026
Figure 28: South America SON Revenue by Country 2021 – 2026
Figure 29: Europe SON Revenue by Country 2021 – 2026
Figure 30: APAC SON Revenue by Country 2021 – 2026
Figure 31: MEA SON Revenue by Country 2021 – 2026
Tables
Table 1: Global SDM Market 2021 – 2026
Table 2: SON Revenue by Platform Type 2021 – 2026
Table 3: SON Revenue by Architecture Type 2021 – 2026
Table 4: SON Revenue by Access Network Technology Type 2021 – 2026
Table 5: SON Revenue by Network Segment Type 2021 – 2026
Table 6: SON Revenue for RAN Optimization by Infrastructure 2021 – 2026
Table 7: SON Revenue for Applications 2021 – 2026
Table 8: SON Revenue by Service Type 2021 – 2026
Table 9: SON Revenue by Professional Service Type 2021 – 2026
Table 10: SON Revenue by Managed Service Type 2021 – 2026
Table 11: Conventional Mobile Network Planning and Optimization Revenue 2021 – 2026
Table 12: Conventional Mobile Network Planning & Optimization Revenue by Region 2021 – 2026
Table 13: SON Revenue by Region 2021 – 2026
Table 14: North America SON Revenue by Country 2021 – 2026
Table 15: South America SON Revenue by Country 2021 – 2026
Table 16: Europe SON Revenue by Country 2021 – 2026
Table 17: APAC SON Revenue by Country 2021 – 2026
Table 18: MEA SON Revenue by Country 2021 – 2026