India Level of Water Stress: Freshwater Withdrawal As Proportion of Available Freshwater Resources data was reported at 66.492 Ratio in 2020. This stayed constant from the previous number of 66.492 Ratio for 2019. India Level of Water Stress: Freshwater Withdrawal As Proportion of Available Freshwater Resources data is updated yearly, averaging 59.848 Ratio from Dec 1975 (Median) to 2020, with 46 observations. The data reached an all-time high of 67.322 Ratio in 2003 and a record low of 39.022 Ratio in 1975. India Level of Water Stress: Freshwater Withdrawal As Proportion of Available Freshwater Resources data remains active status in CEIC and is reported by World Bank. The data is categorized under Global Database’s India – Table IN.World Bank.WDI: Environmental: Water and Wastewater Management. The level of water stress: freshwater withdrawal as a proportion of available freshwater resources is the ratio between total freshwater withdrawn by all major sectors and total renewable freshwater resources, after taking into account environmental water requirements. Main sectors, as defined by ISIC standards, include agriculture; forestry and fishing; manufacturing; electricity industry; and services. This indicator is also known as water withdrawal intensity.;Food and Agriculture Organization, AQUASTAT data.;;

Odisha had the largest combined area of water resources in India, with around 998 thousand hectares of water resources as of 2018. The coastal state largely depends on the southwest monsoons for its water resources along with its surface water and groundwater reserves.

Chilika lake - Puri The state is bestowed with an extensive network of rivers and streams. It also has the largest area of brackish water in the country. The famous Chilika lake, a brackish water lagoon, spreads over a thousand kilometers, is the largest in the country, and the second largest globally. As the most significant breeding ground for migratory birds, the Chilika lake was the first wetland of international importance under Ramsar Convention.

Need for conservation The river system in the country also poses a massive risk to close to five million population annually. Incessant rainfall, consequent floods and cyclonic storms have affected many districts in the state. Between soaring temperatures, natural disasters, and depleting freshwater resources to meet the demands of industrial, domestic, environmental sectors, integrated water resources development and management approach is the need of the hour.

Agricultural water withdrawal as a share of internal resources of India remained constant at 90.41 % over the last 10 years. Agricultural water withdrawal as percentage of total water withdrawal

India Annual Freshwater Withdrawals: Agriculture: % of Total Freshwater Withdrawal data was reported at 90.407 % in 2020. This stayed constant from the previous number of 90.407 % for 2019. India Annual Freshwater Withdrawals: Agriculture: % of Total Freshwater Withdrawal data is updated yearly, averaging 91.593 % from Dec 1975 (Median) to 2020, with 46 observations. The data reached an all-time high of 94.625 % in 1985 and a record low of 90.407 % in 2020. India Annual Freshwater Withdrawals: Agriculture: % of Total Freshwater Withdrawal data remains active status in CEIC and is reported by World Bank. The data is categorized under Global Database’s India – Table IN.World Bank.WDI: Environmental: Water and Wastewater Management. Annual freshwater withdrawals refer to total water withdrawals, not counting evaporation losses from storage basins. Withdrawals also include water from desalination plants in countries where they are a significant source. Withdrawals can exceed 100 percent of total renewable resources where extraction from nonrenewable aquifers or desalination plants is considerable or where there is significant water reuse. Withdrawals for agriculture are total withdrawals for irrigation and livestock production. Data are for the most recent year available for 1987-2002.;Food and Agriculture Organization, AQUASTAT data.;Weighted average;

Water and Wastewater Treatment (WWT) Technology Market Outlook

According to our latest research, the global Water and Wastewater Treatment (WWT) Technology market size reached USD 75.3 billion in 2024, demonstrating robust expansion, and is expected to grow at a CAGR of 6.8% from 2025 to 2033. By 2033, the market is forecasted to attain a value of USD 137.2 billion, driven by escalating water scarcity, tightening environmental regulations, and increasing industrial demand for sustainable water management solutions. The rising necessity for advanced WWT technologies is being propelled by urbanization, population growth, and the need for efficient resource management across municipal, industrial, residential, and commercial sectors.

A primary growth factor in the Water and Wastewater Treatment (WWT) Technology market is the intensification of global water scarcity, which is compelling governments and industries to invest in innovative treatment solutions. As freshwater resources become increasingly limited due to climate change, pollution, and over-extraction, the adoption of advanced WWT technologies such as membrane separation, biological treatments, and chemical processes is accelerating. These technologies not only ensure the availability of potable water but also facilitate the reuse and recycling of treated wastewater, thereby enhancing water sustainability. The growing awareness among stakeholders regarding the importance of water conservation and the implementation of stringent discharge standards are further catalyzing market growth.

Another significant driver is the rapid pace of urbanization and industrialization, particularly in emerging economies. Expanding urban populations and the proliferation of manufacturing facilities are placing unprecedented pressure on existing water infrastructure. This has led to a surge in demand for scalable and efficient WWT technologies capable of addressing both municipal and industrial wastewater challenges. Industries such as oil & gas, power generation, chemicals, food & beverage, and pharmaceuticals are increasingly adopting advanced treatment systems to comply with environmental regulations, minimize operational risks, and achieve sustainability targets. The integration of digital technologies and automation in WWT processes is also enhancing operational efficiency and enabling real-time monitoring, further supporting industry growth.

The evolving regulatory landscape is playing a pivotal role in shaping the Water and Wastewater Treatment Technology market. Governments across the globe are enforcing stricter effluent discharge norms and promoting the adoption of resource-efficient technologies through incentives and subsidies. This regulatory push is particularly pronounced in regions facing acute water stress, where authorities are prioritizing investments in water infrastructure and encouraging public-private partnerships. In addition, the increasing focus on circular economy principles and zero-liquid discharge (ZLD) initiatives is driving the deployment of advanced treatment solutions capable of maximizing water recovery and minimizing environmental impact. The convergence of regulatory, economic, and environmental imperatives is thus creating a fertile ground for technological innovation and market expansion.

Regionally, the Asia Pacific market is emerging as a dominant force in the global Water and Wastewater Treatment Technology landscape, accounting for a significant share of total market revenues in 2024. This growth is underpinned by rapid industrialization, urban expansion, and substantial investments in water infrastructure across countries such as China, India, and Southeast Asian nations. North America and Europe continue to witness steady demand for advanced WWT solutions, driven by mature industrial sectors and stringent regulatory frameworks. Meanwhile, the Middle East & Africa and Latin America are experiencing rising adoption of WWT technologies, spurred by increasing awareness of water scarcity issues and the need to upgrade aging infrastructure. The regional outlook for the market remains highly positive, with Asia Pacific expected to maintain its leadership position through 2033, supported by robust economic growth and proactive policy measures.

Goal 6: Ensure availability and sustainable management of water and sanitation for allIn 2015, 91% of the global population is using an improved drinking water source, compared to 76% in 1990. However, 2.5 billion people lack access to basic sanitation services, such as toilets or latrines.Each day, an average of 5,000 children die due to preventable water and sanitation-related diseases.Hydropower is the most important and widely used renewable source of energy and as of 2011, represented 16% of total electricity production worldwide.Approximately 70% of all available water is used for irrigation.Floods account for 15% of all deaths related to natural disasters.The overall proportion of households in India having access to improved water sources increased from 68% in 1992-93 to 90.6 percent in 2011-12.In 2012, 59% households in rural areas and 8% in urban India did not have access to improved sanitation facilities. Almost 600 million people in India defecate in the open, the highest number in the world.This map layer is offered by Esri India, for ArcGIS Online subscribers, If you have any questions or comments, please let us know via content@esri.in.

As of 2023, approximately ** percent of water bodies around the world registered good water quality. During the same period, five countries reported only ten or less than ten percent of their water bodies with good ambient water quality, among them, India, Burkina Faso, Malta, Indonesia, and Bahrain.

India clean water access for was 0.00%, a 0% increase from .

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</ul>The percentage of people using drinking water from an improved source that is accessible on premises, available when needed and free from faecal and priority chemical contamination. Improved water sources include piped water, boreholes or tubewells, protected dug wells, protected springs, and packaged or delivered water.

Water Storage Systems Market Outlook

The global water storage systems market size was valued at approximately USD 16.5 billion in 2023 and is projected to reach around USD 26.7 billion by 2032, growing at a compound annual growth rate (CAGR) of 5.4% from 2024 to 2032. This market's growth is influenced by increasing urbanization, rising water scarcity issues, and the need for efficient water management systems. Urban populations are expanding rapidly, leading to increased demand for water in residential, commercial, and industrial sectors. As water sources become strained and environmental regulations tighten, the need for robust water storage solutions becomes paramount.

One of the primary growth factors driving the water storage systems market is the escalating global concern over water scarcity and the urgent necessity to optimize water resources. As climate change continues to affect rainfall patterns and exacerbate drought conditions in various regions, the implementation of effective water storage solutions becomes crucial. Governments and private entities are increasingly investing in infrastructure to capture, store, and efficiently distribute water, which is propelling the demand for innovative water storage systems. Technological advancements in materials and design are also enabling the development of more durable and efficient storage solutions, further stimulating market growth.

Another significant driver of growth in the water storage systems market is the rising investment in agriculture and the need for reliable water storage solutions to support irrigation systems. Agriculture accounts for a substantial portion of water consumption worldwide, and as the global population continues to rise, so does the demand for food production. Reliable water storage systems can help ensure consistent water supply for irrigation, even during dry spells, thus enhancing crop yields and food security. This necessity is increasingly recognized by governments and agricultural stakeholders, leading to increased allocations for water infrastructure projects.

Additionally, the industrial sector's demand for water storage systems is contributing significantly to market growth. Industries such as oil & gas, chemical, and food & beverage require substantial water resources for their operations. As these sectors expand and diversify, the demand for efficient and sustainable water storage solutions also rises. Companies are focusing on implementing water storage systems that not only ensure a steady water supply but also comply with stringent environmental and safety regulations. This trend drives the market toward innovative products that offer enhanced functionalities and meet industry-specific needs.

In terms of regional outlook, the Asia Pacific region is anticipated to witness substantial growth in the water storage systems market due to rapid urbanization, industrialization, and increasing water management initiatives. Countries like China and India are investing heavily in infrastructure projects to support their burgeoning populations and economies. Meanwhile, North America and Europe are expected to see steady growth, driven by ongoing upgrades to aging infrastructure and strong regulatory frameworks promoting sustainable water management practices. The Middle East & Africa and Latin America are also poised for growth, although at a slower pace, as they continue to grapple with unique regional challenges related to water scarcity and infrastructure development.

Product Type Analysis

The water storage systems market is segmented by product type, including tanks, reservoirs, standpipes, and others. Tanks are among the most common water storage solutions due to their versatility and adaptability to various environments. They are used extensively across different sectors, from residential to industrial, owing to their ability to store large volumes of water safely and efficiently. The design and material advancements in tanks make them a popular choice for many users, as they can be tailored to specific needs and conditions, including varying climate conditions and spatial constraints.

Reservoirs, another key segment of the water storage system market, play a crucial role in large-scale water storage applications, particularly for municipal and agricultural purposes. They are designed to hold vast quantities of water and are integral to ensuring a steady supply during dry periods or emergencies. The construction and maintenance of reservoirs require significant investment, but their importance in sustaining water supply for large populations and agr

India Annual Freshwater Withdrawals: Industry: % of Total Freshwater Withdrawal data was reported at 2.234 % in 2020. This stayed constant from the previous number of 2.234 % for 2019. India Annual Freshwater Withdrawals: Industry: % of Total Freshwater Withdrawal data is updated yearly, averaging 2.234 % from Dec 1975 (Median) to 2020, with 46 observations. The data reached an all-time high of 4.000 % in 1975 and a record low of 1.638 % in 2000. India Annual Freshwater Withdrawals: Industry: % of Total Freshwater Withdrawal data remains active status in CEIC and is reported by World Bank. The data is categorized under Global Database’s India – Table IN.World Bank.WDI: Environmental: Water and Wastewater Management. Annual freshwater withdrawals refer to total water withdrawals, not counting evaporation losses from storage basins. Withdrawals also include water from desalination plants in countries where they are a significant source. Withdrawals can exceed 100 percent of total renewable resources where extraction from nonrenewable aquifers or desalination plants is considerable or where there is significant water reuse. Withdrawals for industry are total withdrawals for direct industrial use (including withdrawals for cooling thermoelectric plants). Data are for the most recent year available for 1987-2002.;Food and Agriculture Organization, AQUASTAT data.;Weighted average;

India People Using At Least Basic Drinking Water Services: Urban: % of Urban Population data was reported at 95.761 % in 2022. This records an increase from the previous number of 95.582 % for 2021. India People Using At Least Basic Drinking Water Services: Urban: % of Urban Population data is updated yearly, averaging 93.794 % from Dec 2000 (Median) to 2022, with 23 observations. The data reached an all-time high of 95.761 % in 2022 and a record low of 91.829 % in 2000. India People Using At Least Basic Drinking Water Services: Urban: % of Urban Population data remains active status in CEIC and is reported by World Bank. The data is categorized under Global Database’s India – Table IN.World Bank.WDI: Social: Access to Services. The percentage of people using at least basic water services. This indicator encompasses both people using basic water services as well as those using safely managed water services. Basic drinking water services is defined as drinking water from an improved source, provided collection time is not more than 30 minutes for a round trip. Improved water sources include piped water, boreholes or tubewells, protected dug wells, protected springs, and packaged or delivered water.;WHO/UNICEF Joint Monitoring Programme (JMP) for Water Supply, Sanitation and Hygiene (washdata.org).;Weighted average;

Water withdrawals per capita in Turkmenistan amount to 2,740 cubic meters per inhabitant, according to the latest available data from 2021. This is a far higher volume than in many other countries, such as China, where per capita water withdrawals were 398.7 cubic meters as of 2021. Global water withdrawals Countries around the world withdraw huge volumes of water each year from sources such as rivers, lakes, reservoirs, and groundwater. China has some of the largest annual total water withdrawals across the globe, at 581.3 billion cubic meters per year. In comparison, Mexico withdrew almost 90 billion cubic meters of water in 2021. Water scarcity Although roughly 70 percent of Earth's surface is covered with water, less than one percent of the planet's total water resources can be classified as accessible freshwater resources. Growing populations, increased demand, and climate change are increasingly putting pressure on these precious resources. This is expected to lead to global water shortages around the world. In the United States, the megadrought in the west has seen water levels of major reservoirs that provide water to millions of people plummet to record lows. In order to prevent severe droughts in water-stressed areas today and in the future, a more efficient use of water is essential.

The Water Conservancy Informatization market is experiencing robust growth, driven by increasing government investments in infrastructure modernization and the urgent need for efficient water resource management. The market, estimated at $5 billion in 2025, is projected to exhibit a Compound Annual Growth Rate (CAGR) of 12% from 2025 to 2033, reaching approximately $15 billion by 2033. This expansion is fueled by several key factors: the rising adoption of advanced technologies like IoT sensors, AI-powered analytics, and cloud computing for real-time monitoring and data analysis of dams, power stations, and other water infrastructure. Furthermore, stringent government regulations promoting sustainable water management practices and the increasing frequency of extreme weather events necessitate robust water conservancy systems, thus bolstering market demand. The Hardware segment currently dominates the market, accounting for a larger share than the Software segment, but the Software segment is expected to experience faster growth due to the increasing importance of data analytics and predictive modeling capabilities. Key geographic regions contributing significantly to market growth include North America (driven by advanced infrastructure and technological adoption) and Asia-Pacific (led by China and India's significant investments in water resource management). However, high initial investment costs and a lack of technical expertise in some regions pose challenges to market penetration. Competition is relatively fragmented, with various domestic and international players vying for market share. The growth trajectory is expected to remain positive, albeit with some regional variations. While North America and Europe maintain a strong foothold, the Asia-Pacific region is poised for the most significant growth due to substantial infrastructure development projects. The market is likely to witness increased consolidation as companies leverage mergers and acquisitions to expand their service offerings and geographic reach. The focus will shift towards integrated solutions that combine hardware and software capabilities, offering comprehensive data management and predictive analytics for improved water resource management. Innovation in sensor technologies, advanced analytics, and cybersecurity solutions will further shape market dynamics and offer opportunities for new market entrants. Despite some challenges, the long-term outlook for the Water Conservancy Informatization market remains exceedingly promising, reflecting the global imperative for sustainable and efficient water resource management.

This statistic presents the countries with the highest number of people living without access to safe water worldwide in 2017. Almost ** million people living in Nigeria had no household access to safe water at this time.

Lacking water access – additional information

The World Health Organization states that ** liters of water per person per day is the recommended “intermediate” quantity for health, hygiene, and domestic uses. Comparatively, the United States consumed about ***** cubic meters of water per capita in total in 2017. For those who have no direct access to water at home, buying water can be a significant burden, and those that cannot afford it often resort to using water from unsafe sources. The main reasons people struggle to access water is due to a lack of money or political priority, ineffective institutions and management regimes, as well as social inequalities.

There are over *** million people living in India without household access to safe water, a figure higher than many countries have people. Poor management of water resources in India is one of the major problems preventing adequate water access. Aquifers are the main source of water in the country and the use of hand pumps is quickly depleting shallow aquifers. Other countries in Asia, such as Indonesia and Pakistan, have some ** million and ** million people, respectively, who also have to go without safe water in their own homes.

Globally, about 63 percent of the population in Papua New Guinea lives without safe water access in their homes. In the capital city, Port Moresby, many people live in areas that are outside of existing water utilities and infrastructure. More extreme weather and rising sea levels will likely lead to more uncertainty and unreliable water supplies.

Precision Irrigation Market Outlook

According to our latest research, the global Precision Irrigation Market size reached USD 4.23 billion in 2024, driven by the widespread adoption of smart agriculture solutions and the increasing need for efficient water management in farming. The market is projected to grow at a robust CAGR of 11.2% from 2025 to 2033, reaching an estimated USD 11.41 billion by 2033. This impressive growth trajectory is underpinned by rising concerns over water scarcity, technological advancements in irrigation systems, and supportive government initiatives aimed at promoting sustainable agricultural practices worldwide.

The expansion of the precision irrigation market is being significantly fueled by the escalating global demand for food due to a rapidly growing population. As arable land becomes increasingly limited and climate change exacerbates water scarcity, the agricultural sector is under pressure to maximize crop yields with fewer resources. Precision irrigation systems offer a compelling solution by enabling farmers to deliver the right amount of water and nutrients directly to the root zones of plants, thereby enhancing productivity while conserving water. The integration of advanced technologies such as IoT sensors, remote monitoring, and data analytics further amplifies the effectiveness of these systems, making them indispensable for modern agriculture. As a result, the adoption rate of precision irrigation solutions is rising steadily across both developed and developing economies.

Another key growth driver for the precision irrigation market is the increasing emphasis on sustainable farming practices. Governments and international organizations are actively promoting water-efficient irrigation methods through subsidies, incentives, and awareness campaigns. These initiatives are particularly prominent in regions facing acute water shortages, such as the Middle East & Africa and parts of Asia Pacific. Additionally, precision irrigation aligns with the broader trend of digital transformation in agriculture, where data-driven decision-making is becoming the norm. The growing availability of affordable and user-friendly irrigation technologies is lowering the entry barriers for small and medium-sized farmers, further accelerating market expansion. The convergence of sustainability goals and digital innovation is expected to remain a major catalyst for the market over the next decade.

Technological innovation is at the heart of the precision irrigation market’s growth. The development of sophisticated hardware components, such as soil moisture sensors, weather stations, and automated control systems, has revolutionized irrigation management. Coupled with advanced software platforms that provide real-time data analytics and predictive modeling, these solutions enable precise control over irrigation schedules and resource allocation. Service providers are also playing a crucial role by offering installation, maintenance, and consulting services that help end-users optimize their irrigation systems. As the technology matures and becomes more accessible, the adoption of precision irrigation is expected to penetrate new market segments, including non-agricultural applications such as landscaping, sports fields, and urban green spaces.

From a regional perspective, North America currently leads the precision irrigation market, accounting for a significant share of global revenues in 2024. This dominance is attributed to the high level of technological adoption, strong government support, and the presence of large-scale commercial farms in the United States and Canada. However, the Asia Pacific region is emerging as the fastest-growing market, driven by the increasing need for efficient water management in countries like China and India. Europe also holds a substantial market share, supported by stringent environmental regulations and a strong focus on sustainable agriculture. Meanwhile, Latin America and the Middle East & Africa are witnessing growing investments in precision irrigation infrastructure, reflecting the global shift towards water-smart farming practices.

Water Quality Monitoring Sensors Market Outlook

In 2023, the global water quality monitoring sensors market size stands at approximately USD 3.2 billion, and it is projected to reach USD 6.5 billion by 2032, growing at a compound annual growth rate (CAGR) of 8.2% over the forecast period. The market growth is largely driven by increasing environmental regulations and the rising need for water quality management due to urbanization and industrialization.

One of the primary growth factors for the water quality monitoring sensors market is the increasing stringency of environmental regulations worldwide. Governments and regulatory bodies are implementing stringent guidelines to control water pollution and ensure safe drinking water. For instance, the European Union's Water Framework Directive mandates member states to achieve 'good' qualitative and quantitative status of all water bodies. Such regulations compel industries and public utilities to adopt advanced water quality monitoring solutions, propelling the market growth.

Another significant factor driving the market is the rising awareness and concern regarding water scarcity and contamination. With urbanization and industrial activities, the risk of water contamination has surged, threatening human health and environmental balance. This growing awareness has led to increased investments in water quality monitoring technologies, including sensors, to prevent contamination and manage water resources efficiently. Furthermore, advancements in sensor technologies, such as the development of IoT-enabled and real-time monitoring sensors, have enhanced the accuracy and ease of water quality monitoring, further bolstering market demand.

The growing adoption of smart water management systems across various sectors also acts as a catalyst for market growth. Smart water management involves the integration of advanced technologies, including sensors, to monitor, manage, and optimize the use of water resources. This trend is particularly prominent in regions facing water scarcity and those investing in smart city projects. The implementation of such systems not only aids in efficient water management but also supports sustainable development goals, thereby driving the adoption of water quality monitoring sensors.

Regionally, North America and Europe hold significant market shares due to their stringent environmental regulations and high awareness levels. However, the Asia Pacific region is expected to witness the highest growth rate over the forecast period. This growth can be attributed to rapid industrialization, urbanization, and increasing government initiatives aimed at improving water quality. Countries like China and India are investing heavily in water infrastructure and monitoring systems to address the growing concerns of water pollution and scarcity.

Product Type Analysis

The water quality monitoring sensors market is segmented by product types such as pH sensors, dissolved oxygen (DO) sensors, temperature sensors, turbidity sensors, and conductivity sensors, among others. Each type of sensor plays a crucial role in assessing different parameters of water quality, and their demand varies based on specific monitoring needs. For instance, pH sensors are extensively used to measure the acidity or alkalinity of water, which is vital for various industrial processes and maintaining aquatic life. The growing focus on maintaining environmental standards in industries is driving the demand for pH sensors.

Dissolved oxygen sensors are critical in determining the oxygen levels in water bodies, which is essential for aquatic organisms' survival. These sensors are widely used in aquaculture, wastewater treatment, and environmental monitoring. The increasing emphasis on sustainable aquaculture practices and the need for effective wastewater management solutions are significant factors driving the demand for DO sensors. Additionally, advancements in DO sensor technologies, such as optical sensors, have enhanced their accuracy and reliability, further boosting their adoption.

Temperature sensors are another crucial component in water quality monitoring, as water temperature affects various chemical and biological processes. These sensors find applications in groundwater monitoring, surface water monitoring, and industrial processes. The rising need for precise temperature measurements in various applications is fueling the demand for temperature sensors. Similarly, turbidity sensors, which measure the cloudiness or haziness of water, are essential for assessing water

The global smart water management market is projected to reach USD 30.74 billion by 2033, exhibiting a CAGR of 5.14% during the forecast period 2025-2033. The market growth is primarily attributed to increasing water scarcity, aging infrastructure, and government regulations aimed at improving water conservation and efficiency. Additionally, the growing adoption of advanced technologies, such as smart meters, analytics, and remote sensing, is further driving market expansion. In terms of segmentation, the market is divided based on technology, application, end use, deployment, and region. Among technology segments, smart meters hold a significant market share due to their ability to monitor water usage in real-time and identify leaks and inefficiencies. Application-wise, water distribution management accounts for the largest market share, followed by wastewater management and flood management. Residential and commercial sectors are expected to witness substantial growth in smart water management solutions adoption due to increasing awareness about water conservation and the availability of cost-effective technologies. Geographically, North America is anticipated to hold the largest market share throughout the forecast period, with the United States being the key contributor. However, Asia Pacific is projected to exhibit the highest CAGR during the forecast period, driven by rapid urbanization and increasing investments in water infrastructure development in emerging economies like India and China. Recent developments include: , The Smart Water Management Market has recently witnessed several notable developments and current affairs. Companies such as Veolia and SUEZ are advancing their technological offerings, focusing on digital solutions to enhance water efficiency and sustainability. Additionally, Xylem's acquisition of certain assets from Valmont Industries is aimed at expanding its capabilities in water management solutions, reinforcing its position in the market. IBM has also been investing in AI-driven analytics to improve water infrastructure management. Meanwhile, Badger Meter is launching new smart metering technologies to streamline water usage data collection. The market valuation for companies like Schneider Electric and Emerson Electric is on an upward trajectory as municipalities increasingly adopt smart technologies to raise water management efficiency. Companies like Itron are partnering with utilities to innovate water conservation techniques. Furthermore, Aqua America is exploring digital transformation strategies to improve service delivery. These developments indicate a strong movement towards leveraging technology in water management as urbanization and climate challenges necessitate more efficient water use across the globe. The cumulative effect of these advancements is shaping a more integrated and sustainable future for water management systems, driven by major industry players., Smart Water Management Market Segmentation Insights. Key drivers for this market are: Smart irrigation technologies, Water quality monitoring systems; Leak detection solutions; Integration with IoT devices; Advanced data analytics tools. Potential restraints include: Growing water scarcity, Smart metering technology adoption; Government regulations and incentives; Rising infrastructure investments; Sustainable urban development initiatives.

The Atmospheric Water Generator Market size was valued at USD 2.65 billion in 2023 and is projected to reach USD 4.97 billion by 2032, exhibiting a CAGR of 9.4 % during the forecasts period. This growth is primarily driven by the escalating global water scarcity and the increasing adoption of sustainable water solutions. Additionally, government incentives for developing alternative water sources, advancements in technology enhancing water extraction efficiency, and rising consumer awareness about the environmental impact of traditional water sources are significantly contributing to the market's expansion. An Atmospheric Water Generator (AWG) is a device that extracts water from humid ambient air. It operates on principles of condensation, similar to a dehumidifier, cooling the air to collect water droplets. AWGs are valuable in regions with limited access to fresh water but sufficient humidity. They come in various sizes, from household units to large-scale industrial models. Key benefits include providing a sustainable water source, reducing dependency on groundwater, and being a potential solution for water scarcity issues. However, they require significant energy, making efficiency improvements and renewable energy integration critical for widespread adoption. Recent developments include: In August 2023, Spout introduced a new atmospheric water generator, engineered by Bould, capable of generating two and a half gallons of potable water daily. Moreover, the device has the capacity to consistently produce up to 2.5 gallons of water each day. Remarkably, approximately 80% of households worldwide reside in climates with sufficient humidity for the device to operate effectively. , In January 2023, Airiver unveiled its atmospheric water generators for the consumer market. The U.S.-based company's latest offering introduces a sustainable water supply solution for communities in search of convenient access to eco-friendly and purified water. Leveraging minimal power consumption and featuring a multi-stage filtration system capable of removing impurities that conventional filters may miss, Airiver's cutting-edge technology guarantees the production of up to 30 liters of pure, alkaline water daily. , In May 2022, Watergen, in collaboration with SMV Jaipuria Group, an Indian conglomerate, has inked an agreement to introduce its atmospheric water generator technology to India. This Israeli company has introduced its 'GENius' atmospheric water generator technology to address the pressing issue of inadequate access to clean water in India, particularly affecting three-quarters of rural families. Under the terms of the joint venture, SMV Jaipuria Group will oversee the manufacturing of the GENius machines designed to extract potable water from the atmosphere. .

The AMI Water Meter Market is projected to reach USD 4.68 Billion by 2033, exhibiting a CAGR of around 5.37% during the forecast period (2023-2033). Increasing governmental regulations to manage water consumption, rising awareness regarding water scarcity, and the growing deployment of smart water infrastructure drive the market growth. Moreover, technological advancements like IoT and 5G network integration, the proliferation of wireless communication technologies, and initiatives to reduce water wastage further fuel market expansion. However, high implementation costs, privacy concerns, and data security issues may hinder market growth. North America holds the dominant position in the global AMI Water Meter Market due to early adoption of smart water technologies. The growing implementation of smart water meters to monitor water consumption, reduce water loss, and improve efficiency in regions like the United States and Canada contributes to regional growth. Asia-Pacific is expected to witness substantial growth due to increasing urbanization, rising water scarcity, and government initiatives to manage water resources. Countries like China and India are actively investing in smart water infrastructure, further propelling the regional market. AMI Water Meter Market Report Executive Summary The global AMI water meter market is poised to reach a value of USD 15.8 billion by 2028, expanding at a CAGR of 9.6% from 2023 to 2028. The increasing demand for efficient water management, rising water scarcity, and government initiatives are the primary drivers of growth. Recent developments include: , Recent developments in the AMI Water Meter Market highlight a growing emphasis on advanced metering infrastructure and smart water management solutions. Companies like Landis+Gyr and Itron are focusing on the integration of IoT technology to enhance data collection and real-time monitoring capabilities, improving efficiency in water usage and reducing operational costs. Meanwhile, Badger Meter and Sensus are launching new product lines that leverage artificial intelligence for predictive analytics, thus helping utilities manage resources better. In terms of mergers and acquisitions, Aclara's recent acquisition has expanded its market presence and technological capabilities in smart metering solutions, enhancing its positioning amid growing industry competition., Additionally, Honeywell's collaboration with Diehl Metering signals a strategic alliance aimed at achieving sustainable water management through shared technological advancements. Companies like Masco Corporation and Kamstrup are also investing in innovative solutions to cater to the rising demand for sustainable water practices. As the market evolves, the valuation of major players is on the rise, indicating strong future growth potential driven by the increasing need for efficient water management systems., AMI Water Meter Market Segmentation Insights. Key drivers for this market are: Smart city initiatives adoption, Aging infrastructure modernization; Rising environmental regulations; Increased consumer demand for efficiency; Advanced data analytics integration. Potential restraints include: Digital transformation in utilities, Demand for water conservation; Government regulations and incentives; Technological advancements in metering; Growing investment in infrastructure.

According to cognitive market research-"Global Sprinkler Irrigation system market size 2023 was XX Million. Sprinkler Irrigation system Industry compound annual growth rate (CAGR) will be XX% from 2024 till 2031."

  Wheat, maize, barley, soybeans, rice, and other field crops are widely consumed and in great demand globally.
  Stationary or fixed sprinkler systems are currently widely used across geographies, accounting for the majority of the market.
  North America now dominates the market and is projected to continue to do so in the future.
  Asia Pacific is expected to be the fastest-growing region during the projection period due to many factors

Current scenario of the Sprinkler Irrigation system market

Key drivers of the Sprinkler Irrigation system market

Concerns about water scarcity are driving an increase in the use of sprinkler irrigation.

Water scarcity significantly affects food production. Without water, people are unable to water their crops and hence supply food for the fast expanding population. According to the International Water Management Institute, agriculture, which accounts for nearly 70% of worldwide water withdrawals, is continually competing for a limited water supply for household, industrial, and environmental purposes. Many people have attempted to develop more effective water management solutions to address this ever-increasing issue. Irrigation management is one such approach. Irrigation is a method of delivering water to crops in order to maximise agricultural yield. https://thewaterproject.org/water-scarcity/water-scarcity-and-agriculture#:~:text=Water%20Crisis&text=According%20to%20the%20International%20Water,for%20a%20scarce%20water%20supply.

The world is on the verge of a crisis due to increasing population and depletion of water supplies. The agriculture sector prioritizes sustainable measures, including sprinkler irrigation, due to its high water usage. This is expected to positively impact the market. Sprinklers are being used by farmers worldwide, including in major and developing economies like China and India, to cultivate cereals, oilseeds, fruits, and vegetables. As farmers become more conscious of precision farming and accept automation technologies, sprinkler irrigation is expected to grow in popularity.

Government subsidies drive market expansion.

Governments in nations experiencing rapid water resource depletion are embracing sustainable agricultural development methods, with significant sprinkler system subsidies helping to drive market expansion. Government and non-governmental organisation programs are expanding the area covered by sprinkler irrigation while also offering technical assistance to unskilled and small farmers. Government organizations promote precision irrigation methods by providing benefits or subsidies to farmers. In India, the micro irrigation fund (MIF) was established with an initial investment of USD 702.3 million to raise awareness of precision irrigation technologies, notably among food crops such as cotton and sugarcane. The central government also provided a 35% to 45% subsidy for drip irrigation systems, which boosted the precision irrigation systems market. https://pib.gov.in/PressReleasePage.aspx?PRID=1795505

In Europe, various policy initiatives have been established to address sustainable water use in agriculture, such as integrated water management, reuse, research and innovation, and increased environmental interest in agricultural policy. The precision irrigation systems market is predicted to increase significantly, particularly in emerging countries such as Latin America and Asia-Pacific, as a result of favorable government policies involving low-interest loans and subsidies for precision irrigation system installation thus driving the market for sprinkler system.

Constraints for the global Sprinkler Irrigation system market

The high expenses of installing, running, and maintaining sprinkler irrigation systems impede the growth of the sprinkler irrigation sector. tiny-scale farmers, who rely on manual irrigation due to their tiny land area, struggle to deploy mechanised systems due to the large initial expenditure. This is especially true in developing markets such as South America and Asia-Pacific. Precision irrigation systems, such as Albeit in India,...