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スマート水道網の世界市場:2025年~2032年

Global Smart Water Grid Market - 2025-2032

出版日
ページ情報
英文 203 Pages
納期
即日から翌営業日
カスタマイズ可能
適宜更新あり
価格
価格表記: USDを日本円(税抜)に換算
本日の銀行送金レート: 1USD=143.57円
スマート水道網の世界市場:2025年~2032年
出版日: 2025年02月13日
発行: DataM Intelligence
ページ情報: 英文 203 Pages
納期: 即日から翌営業日
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概要

スマート水道網の世界市場は、2024年に294億1,000万米ドルに達し、2032年までには491億5,000万米ドルに達すると予測され、予測期間中の2025年から2032年のCAGRは6.63%で成長します。

スマート水道網市場は、その高度な機能と世界の受け入れの拡大により、かなりの成長が予測されています。リアルタイムのセンシング、品質モニタリング、需要予測、破裂や漏れの効果的な特定など、著しい進歩が水管理システムを変革しています。このような特徴は、世界的に水不足が深刻化する中で、業務効率を改善し、戦略的な計画を容易にし、水の損失を減らすという極めて重要な目標を達成します。

老朽化した水道インフラの改修や正確な課金手法の確立が、市場の成長をさらに後押ししています。水供給システムと管理方法の強化にますます注目が集まっていることは、現代の水問題に取り組む上でスマート水道網が不可欠な機能を持つことを浮き彫りにしています。この進歩には、すでにエネルギー分野に革命をもたらしているスマートグリッド技術の導入が欠かせません。

デジタル・インテリジェンスの活用により、スマートグリッドは水道事業者と消費者の能力を高め、効果的な資源管理を促進し、運用の非効率性を最小限に抑えます。2023年7月、米国は、効率的な電力供給を促進する包括的なインフラを特徴とするスマートグリッドの革命的な能力を例証しました。水部門はこうした開発から利益を得、持続可能な資源管理を促進し、配水・処理システムに関連する二酸化炭素排出を減少させると予想されます。

ダイナミクス

促進要因1-スマート水道網における持続可能性と効率性

持続可能な開発への世界のシフトは、風力、太陽光、バイオ燃料、水力、地熱を含む再生可能エネルギー源への依存を大幅に増加させ、今日では世界のエネルギー生産の15%以上を占めています。この変化は電力インフラに複雑さをもたらし、スマートグリッド技術のような独創的なソリューションを必要とします。

スマートグリッドは、信頼性と回復力を向上させることで、特に水管理における従来のインフラを変革しつつあります。スマートグリッド技術は、障害発生後の迅速なサービス復旧を促進し、停電、費用、ダウンタイムを減少させ、経済的損失を軽減します。クラウドベースのデータ処理と自動化を活用したこれらのシステムは、ビッグデータ分析を通じて状況認識を強化し、資源配分を最適化します。

さらに、停電マッピングなどの技術を組み込むことで、スマートグリッドのデータを予防と復旧の取り組みに最適活用できます。このインフラは、トランスミッションと配電レベルで再生可能エネルギーのシームレスな取り込みを促進し、エネルギー効率を高め、商業用および住宅用の給水システムにおける二酸化炭素排出量を減少させます。

促進要因2-技術の進歩

地理情報システム(GIS)や監視制御・データ収集(SCADA)システムなどの高度な情報技術を取り入れることで、水道システムをリアルタイムで監督・規制する能力が大幅に向上します。地理情報システム(GIS)は、システムの資産とその地理的位置をより正確に描写し、計画と資源配分を強化します。SCADAシステムは、センサーデータの集中集計と処理を容易にし、地理的に分散した資産の制御精度を高めます。

上記の技術は、効率的な資産管理と水損失の削減に不可欠な要素である漏水の迅速な特定と防止を提供します。従来の水供給システムでは、遠隔地の顧客にサービスを提供するために高圧ポンプを維持することが優先されることが多く、特に老朽化したインフラ内では非効率が生じます。スマート水道網は、ほぼリアルタイムのデータ、可変速ポンプ、ダイナミック・コントロール・バルブ、スマート・メーターを使用して、需要を均衡させ、パイプラインの過圧を緩和し、水とエネルギー消費の両方の効率を高めます。このダイナミックでデータ駆動型の手法は、水資源とシステムの最適な管理を促進し、長期的な持続可能性とコスト効率を保証します。

スマート水道システムは、漏水検知の改善、保全イニシアチブの強化、継続的な水質監視を通じて、経済的にも環境的にも大きなメリットをもたらします。このような装置を導入することで、公益事業者は水の損失や不正な接続を検出することができるため、経済的な無駄を最小限に抑え、サービス全体のパフォーマンスを向上させることができます。スマート水道網は、ワイヤレス・データ転送を通じて消費者に水使用量の監視を提供するため、個人が水を節約して光熱費を削減することが可能になり、より持続可能で顧客志向の水管理枠組みが育まれます。

抑制要因:規制と政策の制約

現行の法律は、一般に従来の送電網システムのために策定されたものであり、スマートグリッドの適応性と動的特性に適合していないです。そのため、スマートグリッドの効果的な展開に不可欠な新技術、ビジネスモデル、市場構造を統合するための法的枠組みの改正が急務となっています。

米国では、連邦エネルギー規制委員会(FERC)と各州の規制当局が政策立案において重要な役割を担っていますが、各州間の規制の相違が、統一された効率的なスマート水道網インフラの確立を妨げている可能性があります。規制の違いは、さまざまな地域でスマートグリッド技術の利用を促進する政策の標準化を妨げます。

さらに、政策の不確実性は投資を阻害します。なぜなら、電力会社や利害関係者は、信頼できる支援を提供する明確で安定した政策がなければ、長期的なプロジェクトに関与したがらないからです。センサーやメーターからのリアルタイム・データを含む、スマートグリッドが生み出す膨大なデータを効果的に扱うには、データ収集、保存、分析のための高度なシステムが必要となります。欧州のGDPRのようなデータプライバシー要件に準拠することの複雑さは、公益事業者が消費者の機密情報を不要なアクセスから保護することを保証しなければならないため、問題を悪化させています。

目次

第1章 調査手法と調査範囲

第2章 定義と概要

第3章 エグゼクティブサマリー

第4章 市場力学

  • 影響要因
    • 促進要因
      • スマート水道網における持続可能性と効率性
      • 技術の進歩
    • 抑制要因
      • 規制と政策上の制約
    • 機会
    • 影響分析

第5章 産業分析

  • ポーターのファイブフォース分析
  • サプライチェーン分析
  • 価格分析
  • 規制分析
  • DMIの見解

第6章 コンポーネント別

  • ハードウェア
  • ソフトウェア
  • サービス

第7章 技術別

  • スマートインフラ
  • 制御と自動化
  • ICT・分析ソフトウェア
  • 設計・エンジニアリング

第8章 用途別

  • 住宅用
  • 商業用
  • 産業用

第9章 地域別

  • 北米
    • 米国
    • カナダ
    • メキシコ
  • 欧州
    • ドイツ
    • 英国
    • フランス
    • イタリア
    • スペイン
    • その他欧州地域
  • 南米
    • ブラジル
    • アルゼンチン
    • その他南米
  • アジア太平洋
    • 中国
    • インド
    • 日本
    • オーストラリア
    • その他アジア太平洋
  • 中東・アフリカ

第10章 競合情勢

  • 競合シナリオ
  • 市況・シェア分析
  • M&A分析

第11章 企業プロファイル

  • IBM Corporation
    • 会社概要
    • 製品ポートフォリオと概要
    • 財務概要
    • 主な発展
  • Siemens AG
  • Xylem Inc.
  • Schneider Electric SE
  • Honeywell International Inc.
  • ABB Group
  • Itron Inc.
  • Badger Meter, Inc.
  • Aclara Technologies LLC
  • Trimble Inc.

第12章 付録

目次
Product Code: EP9124

Global Smart Water Grid Market reached US$ 29.41 billion in 2024 and is expected to reach US$ 49.15 billion by 2032, growing with a CAGR of 6.63% during the forecast period 2025-2032.

The smart water grid market is projected for considerable growth, driven by its advanced features and growing global acceptance. Significant advancements like real-time sensing, quality monitoring, demand forecasting and effective identification of bursts and leaks are transforming water management systems. The characteristics improve operating efficiency, facilitate strategic planning and reduce water loss, a progressively vital goal amid escalating worldwide water scarcity.

The refurbishment of old water infrastructure and the establishment of precise billing methodologies further propel the market's growth. The increasing focus on enhancing water supply systems and management methods highlights the essential function of smart water grids in tackling modern water issues. The incorporation of smart grid technology, which is already revolutionizing the energy sector, is crucial to this advancement.

Through the usage of digital intelligence, smart grids enhance the capabilities of water utilities and consumers, facilitating effective resource management and minimizing operational inefficiencies. In July 2023, the US exemplified the revolutionary capabilities of smart grids, featuring comprehensive infrastructure that facilitates efficient electricity delivery. The water sector is anticipated to gain from these developments, promoting sustainable resource management and decreasing carbon emissions associated with water distribution and treatment systems.

Dynamics

Driver 1 - Sustainability and efficiency in the smart water grid

The global shift to sustainable development has significantly increased dependence on renewable energy sources, including wind, solar, biofuels, hydro and geothermal, which today represent over 15% of global energy production. This change introduces increased complexity to power infrastructure, requiring creative solutions such as smart grid technologies.

Smart grids are transforming conventional infrastructure, especially in water management, by improving reliability and resilience. Smart grid technology facilitates swift service restoration following disturbances, decreasing outages, expenses and downtime, therefore mitigating financial losses. Utilizing cloud-based data processing and automation, these systems enhance situational awareness and optimize resource allocation through big data analytics.

Furthermore, incorporating technologies such as outage mapping optimizes the utilization of smart grid data for preventive and restorative initiatives. The infrastructure facilitates the seamless incorporation of renewable energy at transmission and distribution levels, enhancing energy efficiency and diminishing carbon emissions in water supply systems for commercial and residential applications.

Driver 2 - Technological advancement

The incorporation of sophisticated information technologies, including Geographic Information Systems (GIS) and Supervisory Control and Data Acquisition (SCADA) systems, substantially improves the capacity to oversee and regulate water systems in real-time. Geographic Information Systems (GIS) offer a more precise depiction of system assets and their geographical positions, enhancing planning and resource distribution. SCADA systems facilitate the centralized aggregation and processing of sensor data, hence enhancing the precision of control over geographically dispersed assets.

The above mentioned technologies provide the prompt identification and prevention of leaks, an essential component of efficient asset management and the reduction of water losses. Conventional water delivery systems frequently prioritize sustaining high-pressure pumping to service remote clients, resulting in inefficiencies, particularly within deteriorating infrastructure. Smart water grids are used near real-time data, variable-speed pumps, dynamic control valves and smart meters to equilibrate demand, mitigate over-pressure in pipelines and enhance the efficiency of both water and energy consumption. This dynamic, data-driven methodology facilitates the optimal management of water resources and systems, assuring long-term sustainability and cost efficiency.

Smart water systems provide substantial economic and environmental advantages through improved leak detection, enhanced conservation initiatives and ongoing water quality monitoring. The deployment of such devices enables utilities to detect water loss or unauthorized connections, hence minimizing financial waste and enhancing overall service performance. Smart water grids provide consumer monitoring of water usage via wireless data transfer, so enabling individuals to conserve water and reduce utility expenses, fostering a more sustainable and customer-oriented water management framework.

Restraint: Regulatory and policy constraints

Current laws, generally formulated for conventional grid systems, are not compatible with the adaptable, dynamic characteristics of smart grids. Consequently, there is an urgent necessity to revise legislative frameworks to integrate new technology, business models and market structures vital for the effective deployment of smart grids.

In the US, the Federal Energy Regulatory Commission (FERC) and state regulators play essential roles in policy formulation; yet, regulatory differences among states may obstruct the establishment of a unified and efficient smart water grid infrastructure. The regulatory anomalies hinder the standardization of policies that may promote the use of smart grid technologies across various regions.

Furthermore, policy uncertainty inhibits investment, since utilities and stakeholders are reluctant to engage in long-term projects without clear and stable policies that provide dependable support. Effectively handling the extensive data produced by smart grids, encompassing real-time data from sensors and meters, necessitates advanced systems for data collecting, storage and analysis. The intricacy of complying with data privacy requirements, such as the GDPR in Europe, exacerbates the issue, since utilities must guarantee that sensitive consumer information is protected from unwanted access.

Segment Analysis

The global smart water grid market is segmented based on component, technology, application and region.

Advancement in smart water infrastructure for efficient water management

Smart Water Infrastructure (SWI) is an essential component of the modernized water distribution and treatment system, leveraging advanced technologies and data-driven analytics to enhance water resource management. SWI incorporates sensors, Internet of Things (IoT) devices, smart meters and real-time monitoring systems to improve the efficiency and sustainability of water systems.

By continuously monitoring water usage, flow rate and pressure levels, SWI can help utilities reduce water losses, improve water quality and optimize distribution and treatment processes. The technology behind SWI includes advanced data analytics and machine learning algorithms, enabling predictive maintenance, early leak detection and pollution monitoring. These capabilities provide utilities with the tools needed to make informed decisions about water usage and resource allocation.

Additionally, SWI helps utilities respond swiftly to issues, preventing overloading and ensuring efficient water supply management. In August 26, 2024, according to Siemens Smart Infrastructure in a release, the new grid sensor solution will play a pivotal role in digitalising distribution grids, enabling grid operators to achieve full network transparency.

Geographical Penetration

Rising urbanization and water security in North America

The market in North America is experiencing significant growth, driven by the increasing adoption of Automated Meter Reading (AMR) and Advanced Metering Infrastructure (AMI) technologies. The solutions provide utilities with real-time data on water consumption, enabling more efficient water management, improved billing accuracy and enhanced leak detection. North America, particularly US, leads in the installation of AMI systems, representing over 70% of the installed endpoints in Europe and North America in 2019.

The market's expansion is also fueled by rising concerns about water security, particularly the need to reduce Non-Revenue Water (NRW), which includes water lost due to leaks, poor metering and theft. In North America, urbanization, aging infrastructure and rising energy costs are further driving the demand for smart water solutions. The US government's investment in smart grid infrastructure, including the installation of smart water meters, has played a critical role in advancing the market. With projections for a 28% growth in the AMI smart water metering sector in 2024, the market outlook remains positive.

Competitive Landscape

The major global players in the market include IBM Corporation, Siemens AG, Xylem Inc., Schneider Electric SE, Honeywell International Inc., ABB Group, Itron Inc., Badger Meter, Inc., Aclara Technologies LLC and Trimble Inc.

Sustainability Analysis

The Smart Water Grid represents a sustainable approach for contemporary water distribution networks (WDNs), combining Information and Communications Technology (ICT) with traditional water management techniques. SWGs promote operational efficiency, reduce water wastage and improve decision-making by facilitating real-time monitoring and analysis of water consumption. The system mitigates uncertainties associated with conventional inspection methods and enables expedited responses to accidents like as leaks or faulty meters, hence decreasing maintenance expenses.

Real-time data promotes water conservation practices among consumers and enhances the precision of billed consumption. Extensively utilized in industrialized nations like Japan and Singapore, SWGs offer a more regulated and robust distribution system, guaranteeing water sustainability from various sources. Nonetheless, its utilization in nations such as Indonesia is nonetheless constrained. The incorporation of green technology enhances the environmental sustainability of water management, rendering SWGs an essential instrument for future water infrastructure design.

Consumer Behaviour Analysis

Consumer behavior in the smart water grid market indicates an escalating awareness of sustainable water management and a rising need for efficient and dependable water systems. As the worldwide water crisis escalates, urban consumers are increasingly motivated to use innovative technology to improve water usage efficiency, reduce waste and assure sustainable resource management.

The principal factor affecting consumer behavior in this sector is the capacity of SWG systems to deliver real-time data and actionable insights. By facilitating transparency in water usage and providing accurate monitoring, these technologies enable consumers to effectively regulate their consumption and minimize billing conflicts. Moreover, increased environmental awareness is driving households and enterprises to implement technologies that correspond with sustainability objectives.

An exceptional instance of consumer-oriented implementation can be seen in Singapore, where the Smart Water Grid technology supports the Public Utilities Board's (PUB) objective of delivering a dependable water supply around the clock. PUB effectively oversees the water supply network around the island by utilizing sensors and analytical technologies, guaranteeing sustainable water resources for all Singaporeans.

Early Stage Innovations

The smart water grid market is experiencing a significant technological shift, driven by advancements like digital twin technologies and the enhanced use of sensors and artificial intelligence (AI). Significant early-stage advancements in this field encompass solutions aimed at mitigating non-revenue water and optimizing water management procedures.

An exemplary case is the collaboration between Xylem and Idrica, which introduced Xylem Vue powered by GoAigua. This platform consolidates data into a cohesive model, improving the efficiency of water utility operations. The proliferation of AI-driven technology is evident in initiatives such as VA SYD in Sweden, where AI is employed to identify water leaks and decrease non-revenue water by roughly 2%, from 10% to below 8%. The deployment of smart water meters, including the 315,000 NB-IoT meters provided by Vodafone in Spain, illustrates the continuous advancement towards digitalization.

The necessity for enhanced water management is becoming pressing as the global water crisis escalates, affecting 2-3 billion individuals globally who face water scarcity. The industry is experiencing an increase in funding, propelled by government subsidies and initiatives aimed at improving water efficiency and resilience. This financial assistance is expediting the implementation of smart water grid technologies.

Companies are prioritizing water reclamation, automation for process enhancement and cybersecurity to protect digital infrastructure. With water demand projected to rise by 30% by 2050, advances like AI and automation will be crucial for the efficient and sustainable management of water resources. The developments position the smart water grid market for substantial growth, tackling present and future difficulties in water management.

Emerging Market Players and Strategic Initiatives

Emerging players in the smart water grid market are focusing on large-scale initiatives to drive digital transformation and enhance operational efficiency. A prominent example is the Dubai Electricity and Water Authority (DEWA), which on December 30th, 2024, announced the implementation of a smart grid with a total investment of AED 7 billion (US$ 1.9 billion). This ambitious project aligns with the UAE's vision to position Dubai as the smartest and happiest city globally.

The smart grid will enable seamless, 24/7 integrated services, incorporating cutting-edge technologies such as artificial intelligence (AI) and the Internet of Things (IoT). These innovations will facilitate automated decision-making and ensure interoperability across electricity and water networks, contributing to more reliable, efficient and sustainable operations. Such strategic initiatives reflect a growing commitment to leveraging the potential of disruptive technologies to enhance water and energy management in the global smart grid market.

By Component

  • Hardware
  • Software
  • Services

By Technology

  • Smart Infrastructure
  • Control & Automation
  • ICT & Analytical Software
  • Design & Engineering

By Application

  • Residential
  • Commercial
  • Industrial

By Region

  • North America
  • South America
  • Europe
  • Asia-Pacific
  • Middle East and Africa

Key Developments

  • In 23 January 2025, KETOS, a prominent innovator in water intelligence and Siemens, a major technology firm, have collaborated to deliver water quality solutions and enhance water management for operators. The collaboration targets the industrial and municipal water sectors, intending to deliver full water quality control systems.
  • In 09 July 2024, Genus Power Infrastructures Limited, an Indian smart meter company, reported the successful completion of its inaugural shipment of Smart Ultrasonic Water Meters DN20 to Australia, signifying a pivotal advancement in the company's foray into water management systems.

Why Purchase the Report?

  • To visualize the global smart water grid market segmentation based on component, technology, end-user and region, as well as understand key commercial assets and players.
  • Identify commercial opportunities by analyzing trends and co-development.
  • Excel data sheet with numerous data points of the smart water grid market with all segments.
  • PDF report consists of a comprehensive analysis after exhaustive qualitative interviews and an in-depth study.
  • Product mapping available as excel consisting of key products of all the major players.

The global smart water grid market report would provide approximately 62 tables, 53 figures and 203 pages.

Target Audience 2024

  • Manufacturers/ Buyers
  • Industry Investors/Investment Bankers
  • Research Professionals
  • Emerging Companies

Table of Contents

1. Methodology and Scope

  • 1.1. Research Methodology
  • 1.2. Research Objective and Scope of the Report

2. Definition and Overview

3. Executive Summary

  • 3.1. Snippet by Component
  • 3.2. Snippet by Technology
  • 3.3. Snippet by Application
  • 3.4. Snippet by Region

4. Dynamics

  • 4.1. Impacting Factors
    • 4.1.1. Drivers
      • 4.1.1.1. Sustainability and efficiency in the smart water grid
      • 4.1.1.2. Technological advancement
    • 4.1.2. Restraints
      • 4.1.2.1. Regulatory and policy constraints
    • 4.1.3. Opportunity
    • 4.1.4. Impact Analysis

5. Industry Analysis

  • 5.1. Porter's Five Force Analysis
  • 5.2. Supply Chain Analysis
  • 5.3. Pricing Analysis
  • 5.4. Regulatory Analysis
  • 5.5. DMI Opinion

6. By Component

  • 6.1. Introduction
    • 6.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Component
    • 6.1.2. Market Attractiveness Index, By Component
  • 6.2. Hardware*
    • 6.2.1. Introduction
    • 6.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
  • 6.3. Software
  • 6.4. Services

7. By Technology

  • 7.1. Introduction
    • 7.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 7.1.2. Market Attractiveness Index, By Technology
  • 7.2. Smart Infrastructure*
    • 7.2.1. Introduction
    • 7.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
  • 7.3. Control & Automation
  • 7.4. ICT & Analytical Software
  • 7.5. Design & Engineering

8. By Application

  • 8.1. Introduction
    • 8.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 8.1.2. Market Attractiveness Index, By Application
  • 8.2. Residential*
    • 8.2.1. Introduction
    • 8.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
  • 8.3. Commercial
  • 8.4. Industrial

9. By Region

  • 9.1. Introduction
    • 9.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Region
    • 9.1.2. Market Attractiveness Index, By Region
  • 9.2. North America
    • 9.2.1. Introduction
    • 9.2.2. Key Region-Specific Dynamics
    • 9.2.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Component
    • 9.2.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 9.2.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 9.2.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 9.2.6.1. US
      • 9.2.6.2. Canada
      • 9.2.6.3. Mexico
  • 9.3. Europe
    • 9.3.1. Introduction
    • 9.3.2. Key Region-Specific Dynamics
    • 9.3.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Component
    • 9.3.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 9.3.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 9.3.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 9.3.6.1. Germany
      • 9.3.6.2. UK
      • 9.3.6.3. France
      • 9.3.6.4. Italy
      • 9.3.6.5. Spain
      • 9.3.6.6. Rest of Europe
  • 9.4. South America
    • 9.4.1. Introduction
    • 9.4.2. Key Region-Specific Dynamics
    • 9.4.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Component
    • 9.4.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 9.4.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 9.4.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 9.4.6.1. Brazil
      • 9.4.6.2. Argentina
      • 9.4.6.3. Rest of South America
  • 9.5. Asia-Pacific
    • 9.5.1. Introduction
    • 9.5.2. Key Region-Specific Dynamics
    • 9.5.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Component
    • 9.5.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 9.5.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 9.5.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 9.5.6.1. China
      • 9.5.6.2. India
      • 9.5.6.3. Japan
      • 9.5.6.4. Australia
      • 9.5.6.5. Rest of Asia-Pacific
  • 9.6. Middle East and Africa
    • 9.6.1. Introduction
    • 9.6.2. Key Region-Specific Dynamics
    • 9.6.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Component
    • 9.6.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Technology
    • 9.6.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application

10. Competitive Landscape

  • 10.1. Competitive Scenario
  • 10.2. Market Positioning/Share Analysis
  • 10.3. Mergers and Acquisitions Analysis

11. Company Profiles

  • 11.1. IBM Corporation*
    • 11.1.1. Company Overview
    • 11.1.2. Product Portfolio and Description
    • 11.1.3. Financial Overview
    • 11.1.4. Key Developments
  • 11.2. Siemens AG
  • 11.3. Xylem Inc.
  • 11.4. Schneider Electric SE
  • 11.5. Honeywell International Inc.
  • 11.6. ABB Group
  • 11.7. Itron Inc.
  • 11.8. Badger Meter, Inc.
  • 11.9. Aclara Technologies LLC
  • 11.10. Trimble Inc.

LIST NOT EXHAUSTIVE

12. Appendix

  • 12.1. About Us and Services
  • 12.2. Contact Us