Commission for hydrology

Member responsible for thematic area Data Operations and Management

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Member responsible for thematic area Data Operations and Management (submitted by Tony Boston)
19. The development and application of WaterML 2.0 involves close coordination between CHy and the WMO/OGC Hydrology Domain Working Group (HDWG). In particular, the HDWG is developing a suite of hydrology standards known as WaterML 2.0. To date WaterML 2.0: Part 1 (Timeseries), in 2012, and WaterML 2.0: Part 2 (Ratings, Gaugings and Section), in 2015, have been approved as OGC Implementation Standards. Part 1 provides a standard information model for the representation and exchange of water observations time series data, for example of river or lake water levels or discharge. Part 2 defines how to represent rating tables, gauging observations and river cross sections, their associated metadata and vocabularies, as well as a format for exchange of data between organizational systems. Parts 3 (Surface Hydrology Features) and 4 (GroundWaterML2) are in the final stages of being approved and published as OGC standards in 2016-17. The HDWG has also developed a Sensor Observation Service (SOS) profile for hydrology, published in 2014, that defines how WaterML 2.0 time series data can be made available using this OGC web service. HDWG members have also contributed to development of the TimeseriesML standard, published in 2016, which is a more generic implementation of WaterML 2.0: Part 1, which can be used for sharing of time series data from a broader range of scientific domains. Future work will focus on development of additional component parts of WaterML 2.0, with water quality data being an initial focus refining an existing OGC best practice specification. The WaterML 2.0 suite of standards is available from: http://www.opengeospatial.org/standards/waterml and more information on the WMO/OGC Hydrology Domain Working Group is available from: http://www.opengeospatial.org/projects/groups/hydrologydwg.
20. As regards progress on the exchange of hydrological data and products, as well as protocols for providing information on data use, a survey was released in September 2013 on the exchange of hydrological data. Initial results were presented to the WMO/OGC HDWG at that time and were made available to the AWG. A list of commercial and open source software systems supporting OGC services for hydrological data exchange have also been identified. It was noted in the results that better engagement with developing countries through WMO regional associations is essential to broaden understanding of the value of, and to encourage the use of, WaterML 2.0.
21. Extensive work has also been made on testing and applying WaterML 2.0 in pilot projects aimed at demonstrating the value and utility of WaterML 2.0 and providing a basis for it to become a WMO information exchange standard. A project on hydrological data sharing was implemented by the Italian National Hydrology Survey (ISPRA). ISPRA has built a national hydrologic information system for Italy’s federated hydrologic data services from observation sites managed separately in 21 geographic regions across the country. There is a HydroCatalog in Rome that compiles the data from HydroServers in each of the 21 regions. Pilot projects were also developed for several countries and CHy related projects, including China and New Zealand, river basins (Sava, La Plata), regions (Latin America) and WHYCOS Components (Arctic, Niger and SADC). Italy has also developed documentation that supports the exchange of hydrological data using WaterML 2.0. More information on these pilot projects and initiatives in data access and exchange by National Hydrological Services is available from: http://www.wmo.int/pages/prog/hwrp/documents/DataOperationsandManagement_v1-0.pdf.
22. Concerning the monitoring and reporting on new developments dealing with data management issues, such as observations, data exchange and protocols, data transfer formats, data information, as well as the WMO Information System (WIS) and WIGOS, An awareness-raising article was published in the WMO Newsletter, MeteoWorld, entitled Towards a new standard for sharing hydrological data, http://public.wmo.int/en/resources/meteoworld/towards-new-standard-sharing-hydrological-data. An update to the Global Runoff Data Center’s (GRDC) Hydrological Metadata profile of ISO 19115 has also been released, http://www.bafg.de/GRDC/EN/02_srvcs/24_rprtsrs/report_39r2.pdf. The HY_Features: Common Hydrological Feature Model was updated and released as an OGC Discussion Paper. This work has been extensively tested by the HDWG and will form the basis of the WaterML 2.0: Part 3 standard. CHy has contributed to the development of the draft WIGOS Metadata Standard as part of a cross-commission task team. The use of the WMO Information System (WIS) for registering hydrological data services has also been tested.
23. A community of practice on database management systems has been established, based on the open source MCH (Meteorology, Climatology and Hydrology) system. MCH, originally developed in Spanish and installed in several Latin American countries, has been translated into English and French and installed in Ghana, Belize, Curacao, Albania, and Bosnia Herzegovina. In all cases, NHS staff has been trained in the operation and management of the system, http://www.wmo.int/pages/prog/hwrp/mch/.
24. Documentation for the CHy-15 pre-session discussion on standardized data sharing in hydrology was prepared. The material invited comments from the WMO hydrological community on three items which the Commission will make decisions on at CHy-15:

Whether or not to endorse the WMO Hydrological Observing System;

Whether or not to recommend to the WMO Executive Council that WaterML 2.0: Part 1 and Part 2 be adopted as WMO standards for information exchange for use by National Hydrological Services; and

Whether or not to support ongoing adoption by WMO of further WaterML 2.0 standards.

Invited expert responsible for WHOS development (submitted by Silvano Pecora)
25. In early 2013, in response to questions raised by the Inter-Commission Group on the WMO Integrated Global Observing System (ICG-WIGOS) regarding the availability of hydrological observations, the president of the Commission for Hydrology proposed the development of a WMO Hydrological Observing System (WHOS) as the hydrological component of WIGOS. The Commission’s Advisory Working Group endorsed this proposal in September 2014 and, during its seventeenth session in 2015 the World Meteorological Congress urged the promotion of WHOS among NMHSs as well as by the broader hydrological community.
26. WHOS is conceived as a portal for accessing existing online near real-time and historical data, drawing from the water information systems of countries around the world that make their data freely and openly available. It is being developed in two phases with the goal of having it reviewed and endorsed by CHy at its fifteenth session in December 2016. The first phase is the publication of a map interface on the WMO website that links to those NMHSs that make their real-time and/or historical stage and discharge data available online. This map interface was published online in August 2015 and can be accessed at the link http://www.wmo.int/pages/prog/hwrp/chy/whos/. The second phase is a much more comprehensive undertaking aimed at developing a complete services-oriented framework linking hydrologic data providers and users through a hydrologic information system that enables data registration, data discovery, and data access. Such a framework will be fully compliant with the WMO Information System (WIS) as well as WIGOS. The goal is to have an initial implementation of the full capability ready for approval by the Executive Council in June 2018 (EC-70).
27. During the intersessional period following CHy-14, a large number of NHSs were applying standardized techniques in pilot and operational systems for hydrological data exchange. A report on “Global initiatives in hydrological data sharing”, including detailed descriptions about most of the developments in the use of standards for hydrological data exchange, was published on the WMO web portal (http://www.wmo.int/pages/prog/hwrp/documents/DataOperationsandManagement_v1-0.pdf). All these developments allowed the identification of an advanced architecture for the second phase of WHOS, with its fundamental components and essential types of services for sharing hydrologic information across the web. In this context, WHOS is being designed to offer services that support the operational needs of NHSs as well as the broader scientific needs of the international hydrological community. While other interoperability applications have focused on implementing custom data streams (e.g. bridges, adaptors, etc.) between clients and server interfaces, WHOS focuses on a common data and metadata management model that leverages a suite of WMO and OGC standards which can be applied to multiple scientiﬁc communities, in particular hydrologic and atmospheric sciences. Furthermore, WHOS can be integrated within existing data discovery frameworks (e.g. portals, gateways, etc.) by leveraging mediation and brokering services. About its role in WIS, WHOS will publish discovery metadata in GISCs allowing WMO users to access a range of services on WHOS itself. Hydrological discovery metadata were tested in the GISCs in Brasilia, Washington, Offenbach and Melbourne; additional ongoing developments and tests are improving WHOS capabilities in data sharing. The development of WHOS also includes the definition of hydrological observational metadata, providing information on hydrological features of observing stations; when this activity will be completed, it will improve the current WIGOS Metadata Standard and the information available in OSCAR/Surface, one of the principal components of the WIGOS Information Resources. A potential future phase of WHOS is to pilot possible extensions of WIGOS and WIS functions and services tailored to the needs of the hydrological community, but potentially beneficial to other programmes, including databases, simulation models, forecasting chains, web-GIS and other tools.
Member responsible for thematic area Hydrological Forecasting and Prediction (submitted by Yuri Simonov)
28. Further planning and development of the WMO Flood Forecasting Initiative (FFI) strategy was based on a review and assessment of FFI governing documents – FFI Strategy and Action Plan, FFI Activity Plan, and also status of the FFI ongoing and planned projects, undertaken by the two AWG members responsible for hydrological forecasting and prediction. The WMO FFI future strategy was discussed in two FFI Advisory Group meetings (1^st and 2^nd FFI-AG) and the final results of the review and detailed report on the proposed development of the Initiative are presented in the 2^nd FFI-AG Report. In the report all major FFI components (FFGS, SWFDP, CIFDP) were analyzed from the perspective of their adherence to the FFI main goal and objectives, and ways to further improve these projects are proposed. The main achievements for each FFI component are briefly given below.
29. CIFDP is a joint CHy-JCOMM project that aims to improve forecasts in coastal areas that are prone to floods of different origin (river hydrological and oceanographic processes). The project was originally heavily biased to oceanographic modelling and forecasting, without accounting for river hydrological processes in the coastal zone and river–ocean interaction. During the intersessional period CHy managed to achieve several results in the project:

CHy representative now co-chairs the Project Steering Group;

Greater relevance of river hydrological aspects in the project, e.g. a strategy for the river hydrological component was developed, improvements to every subproject were proposed, system developers for river hydrology system were appointed (for CIFDP-Fiji).

30. A more coherent hydrological contribution to this project will help describe coastal processes in their full extent and thus improve inundation forecasting in coastal zones.

31. SWFDP was initially developed to meet the need of meteorologists to better forecast severe weather phenomena. Although this project has been developed in parallel with FFGS in a number of regions (such as the Central Asian region – CARFFG) it was found that the two projects were not efficiently engaged with one another. Recommendations for better communications between the projects were developed. Practical results are evident for the Central Asia region, where an effort was made to better meet FFGS goals by using output information from the SWFDP in the region.
32. FFGS is the most developed project in terms of its hydrological component – a few major improvement paths were indicated: channel routing implementation for large river forecast, ensemble forecasting (using several NWP inputs), debris flow estimation, urban flood forecasting. Such serious upgrades of the system will definitely result in the strengthening of the NHSs capacity to forecast different types of floods, not limited to flash floods. In several regions such forecasting techniques are already being included into operational FFGS. Training programmes were upgraded in order to better serve forecasters in the Central Asia region (including adaptation and translation).
33. As regards the production of the Manual on Flood Risk Mapping, work has been continued – from the reviewing process of previous documents (that for the moment comprise APFM Tool on Flood Risk Mapping), to the development of the table of contents of the proposed manual and development of the first draft and its further review (ongoing task – it is planned for early 2017).
34. As regards interaction with the WMO DRR programme, a review of the WMO DRR Roadmap was done during the intersessional period. One of the activities in which CHy was involved is the development of a hydrological hazard glossary for DRR and its further support of the DRR community. The AWG contributed to development of priorities of actions, recommendations and related roadmap for inter-commission activities to support the implementation of the DRR Work Plan and finalization of the DRR the terms of reference of the DRR Focal Points of Technical Commissions and Programmes.
Member responsible for thematic area Hydrological Forecasting and Prediction (submitted by Johnson M. Maina)
35. A short summary of achievements is presented below.
36. As regards the Flood Forecasting Initiative (FFI), the focus of Mr Maina’s activities focused on:

Championing the WMO FFI main objective: to improve the capacity of meteorological and hydrological services to jointly deliver timely and more accurate products and services required in flood forecasting and warning;

Review of the Guidance Document for the “Assessment of Flood Forecasting Services” and associated “Draft Instruction Manual”;

Capacity-building: training on “operational flood forecasting and warning” for two African countries, namely Benin and Uganda. Other countries have expressed interest in the training. WMO manuals and guidelines supplemented the knowledge used in the training;

Presentations made on “An effective flood forecasting and warning system in Kenya”.

37. With respect to the interaction with the WMO Disaster Risk Reduction (DRR) programme, the following should be mentioned:

Review of the “Peril classification and hazard glossary”, prepared by the Integrated Research on Disaster Risk (IRDR) Working Group on Disaster Loss Data(DATA) Report No. 1, March 2014;

Comments on the WMO DRR Roadmap.

38. Finally, the following were activities undertaken in the area of responsibilities of a general nature:

Presented, jointly with others, a country status report on “Development of a National Policy on Drought”, one of the few published in the final report;

Participated in the design of the NILE BASIN hydrometeorological monitoring network;

Initiated the development of a National Design Storm Database in Kenya;

Participated in all CHy-AWG sessions and related activities.

Member responsible for thematic area Water Resources Assessment (submitted by Antonio Cardoso Neto)
39. The main contribution of Mr Cardoso Neto during the last intersessional period was his participation in the assembling of the Manual of Water Resources Assessment, mainly in organizing and writing one of the case studies to be inserted as part of it. The case study provided by him describes the planning of an important hydrologic basin located in the Brazilian territory. The description of the surveys carried out within the basin includes climate aspects, geological features, pedological characteristics, erosion, biomes and aquatic ecosystems, health aspects, sanitation infrastructure, water supply, urban drainage and the development pressures.
40. The case study furnishes the Brazilian institutional framework based upon which the whole work has been accomplished, such as the legal instruments of the National Water Resources Policy and the components of the National System for Water Resources Management.
41. It also presents the different methodologies used in collecting the various necessary data from industry, livestock, agriculture, mining, human supply, solid waste and evapotranspiration. The main physical and chemical characteristics of the aquifer systems of the basin were described.
42. Surface and ground water have been evaluated in terms of both quality and quantity. Finally, the water balance has been evaluated and then the availability of the water resources of the basin has been estimated.
43. Due to several factors beyond his control, the implementation of a HYCOS component in the Oyapock River Basin, shared by French Guiana and Brazil, has somehow been put on hold for the time being. Nevertheless, efforts have been carried out in order to place this issue “back on the tracks” again.
Member responsible for thematic area Quality Management Framework - Hydrology (submitted by J.F. Cantin)
44. This report describes the progress made in the intersessional period leading to CHy15 in each of the major priority activities of the QMF-H thematic area. It should be noted that in April 2014 Mr Cantin succeeded Mr P. Pilon, who had been elected by CHy-14 as the AWG member responsible for QMF-H.
45. The Management Committee (MC) of the CHy project for the Assessment of the Performance of Flow Measurement Instruments and Techniques (familiarly known as Project X) held 12 teleconferences and met twice during the period. Significant progress has been made to generate a software package to estimate uncertainty in discharge measurements performed by NHSs of WMO Members that will be made available to NHSs via the internet from a WMO portal. Specifications were developed and used to support the development of a calculator for the estimation of uncertainty of measurements from the application of the Velocity-Area method. Further developments regarding ADCP measurements are expected during the next intersessional period. During the next intersessional period, the Project X Management Committee will assess the opportunity to publish the guidance material that has been developed regarding guidelines for conducting and reporting results of instrument calibration and performance tests on instruments and techniques.
46. A website for QMF-H was designed and populated with material explaining why NHSs should use standardized methods in their data collection, thereby responding to the request of CHy-14. Guidance material, case studies and a checklist to facilitate the NHSs efforts in implementing a Quality Management System (QMS) were also developed and made available on the QMF-H website: http://www.wmo.int/pages/prog/hwrp/qmf-h/index.php.
47. As regards the review of CHy regulatory material, coordination activities were conducted by Secretariat personnel and the AWG member responsible for QMF-H to outline CHy efforts in QMF-H and present its regulatory, guidance and technical material on various inter-Commissions forums. A strategy to address the overall CHy regulatory material in the context of the Roadmap to Enhanced WMO Technical Regulations Framework endorsed by EC68 has been developed and will be discussed during CHy-15.
48. The AWG member responsible for QMF-H also represented CHy on the WIGOS Editorial Board (WEdB).
_________
ANNEX 3
[Copied from CHy-15/INF 2.3]
REPORT BY THE SECRETARY-GENERAL AND REGIONAL ACTIVITIES
RELATED TO THE HWRP

The present document contains a brief report of the activities undertaken in the last intersessional period (2013-2016) under the framework of the Hydrology and Water Resources Programme, which Cg-17, through Resolution 18 (Cg-17), decided to maintain as described in the Abridged Final Report with Resolutions of the Sixteenth World Meteorological Congress (WMO-No. 1077), Annex II – WMO Programme descriptions. The focus of this document is on those issues not reported by the president of the Commission (see CHy-15/Doc. 2) or by the AWG members (see CHy-15/INF. 2.2).

BASIC SYSTEMS IN HYDROLOGY
Global Hydrometry Support Facility (GHSF)

The president of CHy, together with the Secretariat, developed a proposal for a Global Hydrometry Support Facility (GHSF), which the Swiss Agency for Development and Cooperation (SDC) will support for the 2017-2020 period, in particular by financing three professional project positions.

The GHSF is designed to consolidate national monitoring capabilities and their regional and global integration, and is a support to the WHYCOS programme through the development and application of innovative monitoring and database technologies. GHSF includes WHYCOS, WHOS, a global Innovation Hub, a Hydrological Services Information Platform and a Help Desk.

Scope of GHSF

There is a need for a new paradigm in hydrometry for an effective decision-support to integrated water resources management, particularly in areas where resource scarcity, fragile conditions, conflicts, highly variable supplies, and rapid demand growth overlap with underfunded agencies.

Recent assessments continue to show a decline of monitoring networks, related to lack of financial resources and qualified staff, and generally speaking a low visibility and recognition of Hydrological Services by national authorities. A new paradigm in water monitoring is required.

Coordination and innovation are needed to propose new approaches that:

Build, enhance, and maintain national and regional hydrological observing systems where they are weak and where knowledge gaps are threatening sustainable development;

Promote regional and global coordination and integration of monitoring systems and dissemination of their products/benefits notably in relation to the Sustainable Development Goals (SDG);

Support quality control, processing, exchange, and storage of data from observing systems;

Foster evidence-based policy and decision-making in support of integrated water resources management from political, financial and operational standpoints by generating derived products and develop information systems;

Support the development of new data acquisition methodologies including and combining technology and community-based approaches;

Foster joint analysis of data in order to catalyse and improve transboundary and regional cooperation and support stakeholders in their capacity development, in order to improve sustainable and secure water management and avoid tensions and conflicts.

The elements of the implementation strategy for each GHSF component are described in CHy-15/Doc. 4.1(2). What follows is a brief description of the status of each component at the time of writing this report.

WHYCOS

The World Hydrological Cycle Observing System (WHYCOS) is the long-standing initiative dedicated to water monitoring networks, including planning and installation of monitoring stations (water quantity and quality, surface and groundwater), strengthening transboundary and international cooperation and promoting the free exchange of hydrological data. Started in 1993, WHYCOS is implemented through regional HYCOS projects. The current status of the different projects can be found under http://www.whycos.org/whycos. As of December 2016, approximately 15 projects have been developed, three are on-going (Arctic, IGAD and Niger-HYCOS), and five are in the preparation phase, looking for funding (Congo, Lake Chad, Senegal Basin and phase 3 of SADC and Niger). Pacific HYCOS and Niger-HYCOS are also considering starting a new phase.

Numerous HYCOS projects have been considered in other regions (Amazon, Black Sea, Danube, South-East Asia, etc.), but haven’t been implemented mainly due to a lack of interest of financial partners, but also from now and then to a lack of interest of country partners. Other regions, having recognized the benefit of WHYCOS, have shown interest, as for instance the island countries of the Indian Ocean, Aral Sea, Oyapock basin, etc.

Starting new projects according to country requirement and priorities is crucial, but it is even more essential to guarantee the sustainability of the implemented HYCOS projects, in terms of operation and maintenance of hydrological stations, data management and hydrological products and services delivery. A long-term financial and technical strategy must be put in place.

Innovation Hub
11. Rapid developments in low-cost open-innovation sensors, communication technology and in data synthesis, provide new perspectives for increased data coverage, effective data management, and secure data exchange, as well as the production of knowledge for effective and sustainable resource management. (See also:

http://www.whycos.org/wordpress/wp-content/uploads/2016/08/GHSF-concept-note.pdf).

A pilot study called “the innovative monitoring and modelling approach” (iMoMo) that the Swiss Agency for Development and Cooperation (SDC) has been promoting since 2012, has recently achieved proof-of-concept status in different countries of the World. iMoMo is a practicable example of what the Innovation Hub of the GHSF can develop in the future.

WHOS

The WMO Hydrological Observing System (WHOS) envisions being a services-oriented framework linking hydrologic data and users. It should fulfill the long sought goal of hydrologists and water resources specialists worldwide to have simple access to hydrological information from those NMHSs around the world that make their data freely and openly available.

In 2014 the president of CHy, with the support of the AWG, proposed the establishment of WHOS. After working on the concept, the president presented his proposal to Cg-17 in 2015. Congress welcomed the effort and urged the president of CHy to continue guiding WHOS to full implementation. WHOS was conceived as the hydrological input to WIGOS to be implemented in two phases, the first, launched in July 2015, consisting of an online portal for accessing existing near real-time and historical hydrological information, and allowing NHSs to publish their data and other hydrological information (see the WHOS homepage for further information).

The second phase aims at developing a complete services-oriented hydrologic information system that enables data registration, discovery and access, in compliance with WIS and WIGOS. WHOS will support storage of hydrological information, its publication on the Internet via web-services, combining it with hydrological data published by multiple sources, and search across the various data holdings within a network. Some developments could be combined with those of the GEOSS Common Infrastructure of the Group on Earth Observations, which has similar objectives. CHy-15 will set up a process to develop an implementation plan, including a timetable, for the phase II of WHOS.

It is to be noted that providers will remain the owner of their data; WHOS is facilitating their visibility and access for national, regional and global needs. One requirement will be to use standardized data exchange formats. WHOS will form a specialized hydrological registry within WIS, will be open to all users and institutions from any country or level of government, and will apply to any type of hydrological information.

Hydrological Services Information Platform

In 2013, concerned that hydrological information and services systems in developing countries were deteriorating, the Global Facility for Disaster Reduction and Recovery (GFDRR) and the Water Partnership Program (WPP) from the World Bank Group and the Hydrology and Water Resources Department (HWRD) of WMO embarked on an assessment of the state of hydrological services in developing countries. The GFDRR, WPP and WMO believe that there is an increasing demand for hydrometeorological and climate information and services around the world.

Phase 1 of the assessment commenced with a rapid global assessment based on available literature, including, inter alia, the Hydrological Information Referral Service (INFOHYDRO).

The rapid global assessment (World Bank Group, December 2014) identified the following issues with respect to hydrological information and services systems:

Low visibility and recognition by national authorities;

Lack of financial resources for operation and maintenance activities;

Decline of monitoring systems, obsolescence of equipment;

Lack of qualified staff;

Defective communication and data management system;

An inability for National Hydrological Services (NHSs) to meet current user demands.

The rapid assessment recommended the implementation of a number of targeted case studies to review the status of hydrological information and services systems in developing countries and proposed the establishment of National Hydrological Data Users Groups (NHDUG) to assist and support NHSs in establishing their roles and responsibilities in national development planning as part of the review process.

These case studies were requested to address the following proposals:

Improved assessment of the status of NHSs globally is necessary;

Support is necessary to help NHSs raise their profiles and evolve into demand driven, service oriented organizations. Establishment of a national hydrological services user group;

Countries should develop National Action Plans for Operational Hydrology, within the Framework of National Development Strategies.

As a result, Phase 2 of the project (the case studies) was conducted over the period 2015 to 2016. Phase 2 has seen targeted initiatives aimed at assessment of the state of hydrological services and recommendations for their improvement in selected countries, namely in Cameroon, Madagascar, Senegal, St. Lucia, Tanzania and Uruguay.

Based on the outcomes from these targeted studies and information collected from approximately 60 other studies covering 43 developing countries, some specific findings have been drawn, including the following:

70% (31) of the countries had some (albeit limited) level of understanding of the uses and users of hydrological information and services. For 30% (12) of countries, information on the uses and users was lacking;

Whilst the information provided is not consistent, the status of hydrological networks can be defined as:

7% (3) of countries described their networks as adequate and in relatively good shape;
19% (8) of countries have recently been provided with funds to upgrade networks that were in a significant state of decline;
26% (11) of countries had networks that were in a significant state of decline (less than 25% operational);
30% (13) of countries had networks that were in a poor state (less than 50% operational);
12% (5) of countries provided specific evidence of declining networks;
7% (3) of countries had no information on which to make an assessment.

With respect to data management, 70% (30) of countries are in need of upgrades to their data management systems, 9% (4) of countries are in the process of upgrading their data management systems, 9% (4) of countries expressed a level of satisfaction with their current database, whilst 12% (5) countries had no information on which to make an assessment;

Information on hydrological services delivered was inconsistent and insufficient to draw specific conclusions, but in the main, apart from a small number of targeted services (such as flood forecasts) and some basic hydrological statistics, there was little evidence of provision of adequate hydrological services in the majority of countries;

The greater majority of countries identified staff numbers and staff training/capacity-building as inadequate and therefore requiring attention;

Limited information was available on the levels of user satisfaction with the hydrological services provided in the countries.

The above assessment is consistent with the findings of the 2014 World Bank Group assessment which reported that 72% of water professionals surveyed had stated that their country was in need of more water monitoring stations and that 78% of Developing Countries and 86% of Least Developed Countries consider that their networks do not meet the current needs.

The World Bank Group (GFDRR and WPP) and WMO are now implementing Phase 3 of the project which is aimed at further evaluation of the information collected and the provision of guidance to international organizations, non-governmental organizations, donors, development partner agencies, governments and NHSs on how to develop business case-based approaches for the operations and management of NHSs, so that they can better contribute to National Development Strategies.

In particular, information on funding of NHSs is being sought so that baseline government contributions to the public good activities of NHSs can be established.

The World Bank Group (GFDRR and WPP) and WMO are seeking guidance and support from CHy-15 in moving forward with Phase 3 of the project. In particular, they would like to know:

Are GFDRR, WPP and WMO correct in their assessment?

Can NHSs support the approach proposed?

What can NHSs contribute in the way of supporting information?

How can GFDRR, WPP and WMO help NHSs?

What can be done by WMO?

What can be done by donors/development partners?

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