按技術、基礎設施、解決方案和服務劃分的自組織網絡 (SON) 市場（2022-2027 年）

本報告考察了自組織網絡 (SON) 市場，並對自組織網絡 (SON) 特性和解決方案、部署和運營優勢、部署、運營、優化和未來挑戰進行了技術評估。它提供了業務挑戰、市場分析和預測、關鍵參與者信息等。

調查摘錄

• 到 2027 年，多供應商自組織網絡 (SON) 平台的全球市場規模預計將達到 87 億美元
• 全球自組織網絡 (SON) 安全解決方案和更新市場規模預計到 2027 年將達到 109 億美元
• 用於非網絡功能（例如業務數據分析）的自組織網絡 (SON) 的使用量將增加
• 自組織網絡 (SON) 將用於基於網絡的位置分析，以補充智能手機 GPS

內容

第 1 章執行摘要

第 2 章自組織網絡 (SON) 技術概述

• 向異構網絡演進
• 3GPP 第 11 版中的自組織網絡 (SON)
  • 版本 8、9 和 10 標準化
  • 3GPP 第 8 版
  • 3GPP 第 9 版
  • 3GPP 第 10 版
  • 3GPP 第 11 版
• 自組織網絡 (SON) 概述
• 自組織網絡 (SON) 的優勢
  • 網絡自動化
  • 節能
  • 降低設備成本
  • 分佈式/自組織
  • 自組織網絡 (SON) 中的協作中繼
  • 自組織網絡 (SON) 反饋開銷
  • 基於碼本的預編碼自組織網絡 (SON)
  • 自組織網絡 (SON) 反饋延遲

第 3 章自組織網絡 (SON) 用例和市場狀況

• 自組織網絡 (SON) 的應用
  • 自行配置
  • 自我優化
  • 自我修復
  • 自我修復問題
• 實施和操作選項
• 自組織網絡 (SON) 版本
• 自動鄰居關係
• 自組織網絡 (SON) 負載平衡
• 移動穩健性優化
• 自組織網絡中的分佈式集群 (SON)
• 運營用例
• 加強 ICIC
• 城市自組織網絡 (SON)
  • 部署到房屋/房屋
  • 部署到公司
  • 部署到地鐵和公共場所
  • 向區域擴展
  • 自組織網絡 (SON) 和小型蜂窩部署

第 4 章自組織網絡 (SON) 和智能天線

• 電動傾斜
• 機械傾斜
• 自組織網絡 (SON) 與自組織網絡 (SON) 相關技術/解決方案
• 天線傾斜安裝及其參數
• 天線傾斜功能和投資回報率

第 5 章。自組織網絡 (SON) 的商業價值

• NGMN 用例
• 運營商福利
• 運營商的自組織網絡 (SON) 價值觀
  • 經濟效益
  • 自組織網絡 (SON) 的引入成本
  • 自組織網絡 (SON) 資本投資
  • 自組織網絡 (SON) 運營成本
  • 更智能的自組織網絡 (SON)
• 運營商部署 LTE 的建議

第 6 章自組織網絡 (SON) 供應商格局

• Airhop Communications
• Airspan
• Amdocs
• Ascom Holding AG
• BLiNQ Networks
• Bwtech
• Casa Systems
• CCS（Cambridge Communication Systems）Ltd.
• Cellwize Wireless Technologies Pte Ltd.
• Cisco
• Comarch
• Commscope
• Ericsson
• Huawei Technologies Co., Ltd.
• Mera
• NEC
• Nokia
• P.I. Works
• Qualcomm
• RadiSys Corporation
• Reverb Networks
• Rohde & Schwarz
• Siemens AG
• Teoco Corporation
• Verizon
• Viavi Solutions
• ZTE Corporation

第 7 章自組織網絡 (SON) 市場分析與預測 (2022-2027)

• 全球自組織網絡 (SON) 市場
• 按平台類型劃分的自組織網絡 (SON) 收入
• 按架構類型劃分的自組織網絡 (SON) 收入
• 按接入網絡技術類型劃分的自組織網絡 (SON) 收入
• 按網絡分段類型劃分的自組織網絡 (SON) 收入
• 通過基礎設施優化 RAN 的自組織網絡 (SON) 收入
• 應用程序的自組織網絡 (SON) 收入
• 按服務類型劃分的自組織網絡 (SON) 收入
• 傳統移動網絡規劃優化收益
• 按地區劃分的傳統移動網絡規劃與優化收入
• 按地區劃分的自組織網絡 (SON) 收入
  • 北美國家/地區的自組織網絡 (SON) 收入
  • 按國家/地區劃分的南美洲自組織網絡 (SON) 收入
  • 按國家/地區劃分的歐洲自組織網絡 (SON) 收入
  • 按國家/地區劃分的亞太地區自組織網絡 (SON) 收入
  • 按國家/地區劃分的中東和非洲自組織網絡 (SON) 收入

Overview:

This report evaluates Self Organizing Network (SON) capabilities and solutions. It analyzes the function of SON and evaluates the benefits of deployment and operation. The report includes forecasts from 2022 through 2027. The report is a balance between technical assessment of SON in terms of implementation, operations, optimization, and future issues with business issues.

The business issues and opportunities sections provide critical analysis of the impact of SON from a cost savings and network efficiency perspective. Wireless carrier business operations groups will want to pay particular attention to the issues evaluated in this research to better understand the post-SON network.

Select Report Findings:

• The global multi-vendor SON platform market will reach $8.7B USD by 2027

• The global market for SON security solutions and updates will reach $10.9B by 2027

• SON will increasingly be used for non-network functions including business data analytics

• SON will be relied upon for location analytics as a network-based complement to smartphone GPS

LTE and 5G provide substantial benefits to wireless carriers including greater capacity for wireless applications and services. This greater supply of bandwidth will stimulate the development, implementation, and operation of many new applications, each with a very unique quality of service, bandwidth, and performance needs.

5G networks in particular will be much more complex and this will facilitate a need for improved operations and OSS. 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:

Table of Contents

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
  • 2.4.5. Cooperative Relaying in SON
  • 2.4.6. SON Feedback Overhead
  • 2.4.7. Codebook-based Precoding 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 2022-2027
• 7.2. SON Revenue by Platform Type 2022-2027
• 7.3. SON Revenue by Architecture Type 2022-2027
• 7.4. SON Revenue by Access Network Technology Type 2022-2027
• 7.5. SON Revenue by Network Segment Type 2022-2027
• 7.6. SON Revenue for RAN Optimization by Infrastructure 2022-2027
• 7.7. SON Revenue for Applications 2022-2027
• 7.8. SON Revenue by Service Type 2022-2027
  • 7.8.1. SON Revenue by Professional Service Type 2022-2027
  • 7.8.2. SON Revenue by Managed Service Type 2022-2027
• 7.9. Conventional Mobile Network Planning and Optimization Revenue 2022-2027
• 7.10. Conventional Mobile Network Planning and Optimization Revenue by Region 2022-2027
• 7.11. SON Revenue by Region 2022-2027
  • 7.11.1. North America SON Revenue by Country 2022-2027
  • 7.11.2. South America SON Revenue by Country 2022-2027
  • 7.11.3. Europe SON Revenue by Country 2022-2027
  • 7.11.4. APAC SON Revenue by Country 2022-2027
  • 7.11.1. MEA SON Revenue by Country 2022-2027

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 2022 - 2027
• Figure 15: SON Revenue by Platform Type 2022 - 2027
• Figure 16: SON Revenue by Architecture Type 2022 - 2027
• Figure 17: SON Revenue by Access Network Technology Type 2022 - 2027
• Figure 18: SON Revenue by Network Segment Type 2022 - 2027
• Figure 19: SON Revenue for RAN Optimization by Infrastructure 2022 - 2027
• Figure 20: SON Revenue for Applications 2022 - 2027
• Figure 21: SON Revenue by Service Type 2022 - 2027
• Figure 22: SON Revenue by Professional Service Type 2022 - 2027
• Figure 23: SON Revenue by Managed Service Type 2022 - 2027
• Figure 24: Conventional Mobile Network Planning & Optimization Revenue 2022 - 2027
• Figure 25: Conventional Mobile Network Planning & Optimization Revenue by Region 2022 - 2027
• Figure 26: SON Revenue by Region 2022 - 2027
• Figure 27: North America SON Revenue by Country 2022 - 2027
• Figure 28: South America SON Revenue by Country 2022 - 2027
• Figure 29: Europe SON Revenue by Country 2022 - 2027
• Figure 30: APAC SON Revenue by Country 2022 - 2027
• Figure 31: MEA SON Revenue by Country 2022 - 2027

Tables

• Table 1: Global SDM Market 2022 - 2027
• Table 2: SON Revenue by Platform Type 2022 - 2027
• Table 3: SON Revenue by Architecture Type 2022 - 2027
• Table 4: SON Revenue by Access Network Technology Type 2022 - 2027
• Table 5: SON Revenue by Network Segment Type 2022 - 2027
• Table 6: SON Revenue for RAN Optimization by Infrastructure 2022 - 2027
• Table 7: SON Revenue for Applications 2022 - 2027
• Table 8: SON Revenue by Service Type 2022 - 2027
• Table 9: SON Revenue by Professional Service Type 2022 - 2027
• Table 10: SON Revenue by Managed Service Type 2022 - 2027
• Table 11: Conventional Mobile Network Planning and Optimization Revenue 2022 - 2027
• Table 12: Conventional Mobile Network Planning & Optimization Revenue by Region 2022 - 2027
• Table 13: SON Revenue by Region 2022 - 2027
• Table 14: North America SON Revenue by Country 2022 - 2027
• Table 15: South America SON Revenue by Country 2022 - 2027
• Table 16: Europe SON Revenue by Country 2022 - 2027
• Table 17: APAC SON Revenue by Country 2022 - 2027
• Table 18: MEA SON Revenue by Country 2022 - 2027