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Handbook on Use of Radio Spectrum for Meteorology: Weather, Water

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Handbook on Use of Radio Spectrum for Meteorology: Weather, Water ITU-R Internati onal Handbook on Telecommunicati on Union Place des Nati ons Use of Radio Spectrum for Meteorology: 1211 Geneva 20 Switzerland Weather, Water and Climate Monitoring and ISBN 978-92-61-24881-9 SAP id Prediction 4 1 4 2 2 Editi on of 2017 9 7 8 9 2 6 1 2 4 8 8 1 9 Printed in Switzerland Geneva, 2017 Photo credits: Shutt erstock HANDBOOK Use of Radio Spectrum for Meteorology: Weather, Water and Climate Monitoring and Prediction Edition of 2017 Radiocommunication Bureau W orld Meteorological Organization WMO-ITU 2017 All rights reserved. No part of this publication may be reproduced, by any means whatsoever, without the prior written permission of ITU. Use of Radio Spectrum for Meteorology: Weather, Water and Climate Monitoring and Prediction iii PREFACE “Climate change threatens to have a catastrophic impact on ecosystems and the future prosperity, security and well-being of all humankind. The potential consequences extend to virtually all aspects of sustainable development- from food, energy and water security to broader economic and political stability” António Guterres, UN Secretary-General WMO - World Meteorological Congress ITU World Radiocommunication Conference (Geneva, 2015), in Resolution 29 (Cg-17): (Geneva, 2012), in Resolution 673 (WRC-12): Considering: “considering The prime importance of the specific … radiocommunication services for b) that Earth observation data are also meteorological and related environmental essential for monitoring and predicting climate activities required for the detection and early changes, for disaster prediction, monitoring warning of hazards and and mitigation, for increasing the safety of life and property, the protection of understanding, modelling and verification of the environment, climate change studies and all aspects of climate change, and for related scientific research; policy-making; … … Stressing e) that many observations are performed over that some radio-frequency bands are a unique the entire world which require spectrum- natural resource due to their special related issues to be considered on a worldwide characteristics and natural radiation enabling basis; space-borne passive sensing of the atmosphere … and the Earth, which deserve adequate h) that Earth observations are performed for allocation to the Earth-exploration satellite the benefit of the whole international service (passive) and absolute protection from community and the data are generally made interference; available at no cost, … … Urges all Members resolves to do their utmost to ensure the availability and 1 to continue to recognize that the use of protection of suitable radio-frequency bands; spectrum by Earth observation applications has … a considerable societal and economic value; Appeals to the International 2 to urge administrations to take into account Telecommunication Union and its Member Earth observation radio-frequency Administrations requirements and in particular protection of the (1) To ensure the availability and absolute Earth observation systems in the related protection of the frequency bands; passive sensing radio-frequency bands which, 3 to encourage administrations to consider the due to their special physical characteristics, are importance of the use and availability of a unique natural resource for spaceborne spectrum for Earth observation applications passive sensing of the atmosphere and the prior to taking decisions that would negatively Earth surface and are of crucial importance for impact the operation of these applications.” weather, water and climate research and operations; (2) To give due consideration to the WMO requirements for radio-frequency allocations and regulatory provisions for meteorological and related environmental operations and research; … iv Use of Radio Spectrum for Meteorology: Weather, Water and Climate Monitoring and Prediction Between 1970 and 2015, more than 12 000 natural disasters worldwide took the lives of over 3.5 million people and produced economic losses estimated at over 2.7 trillion US dollars. Ninety per cent of these natural disasters, more than 60% of casualties and 70% of economic losses were caused by weather-, climate- and water-related hazards, such as droughts, floods, severe storms and tropical cyclones as well as by health epidemics and insect infestations directly linked to meteorological and hydrological conditions. These extreme events are intensifying with climate change, the “defining challenge of our time”, and will continue to do so if it is left unaddressed. There is indeed overwhelming scientific evidence that climate change will threaten economic growth, long term prosperity and social welfare of practically all countries, as well as the very survival of the most vulnerable populations. In understanding and addressing climate change and its impacts, observation and monitoring technologies and infrastructure play a critical role. At present, radio-based applications such as remote sensing instruments operating on-board satellites and on the earth surface (e.g. weather radars) provide the main source of information about the Earth’s atmosphere and surface. In turn, this information is used for climate, weather and water monitoring, prediction and warnings, natural disasters risk reduction, support of disaster-relief operations and for planning preventive measures for adapting to and mitigating the negative effects of climate change. Areas foreseen in this context include: continued observations and long-term monitoring of solar activity to improve our knowledge and understanding of the influence of the electromagnetic radiation from the sun on Earth's environment, including climate; continued observations to characterize changes in the atmosphere, oceans, land surface, and the cryosphere, and the use of such information for climate change modelling; and continued observations of the change in the ozone layer and its effects on the environment and human health. Land cover change assessment and understanding of its dynamics are recognized as essential requirements for sustainable management of natural resources, environmental protection, food security, climate change and humanitarian programmes. Terrestrial and satellite radiocommunication systems contribute to the monitoring of carbon emissions, the changing of ice in polar caps and glaciers, and temperature changes. For more than 140 years, starting with the International Telegraph Union and the International Meteorological Organization in the late 1800s, to respectively become the International Telecommunication Union (ITU) and the World Meteorological Organization (WMO) in the 1950s, there has been fruitful collaboration and partnership between the global meteorological and telecommunication agencies. Whilst WMO focuses its efforts on meeting the needs for environmental information and the corresponding radio frequency spectrum for standardized weather, climate and hydrological applications, ITU, as international steward of the radio spectrum, allocates the necessary radio frequencies to allow the interference-free operation of radio-based applications and radiocommunication systems (terrestrial and space) used for climate monitoring and prediction, weather forecasting and disaster early warning and detection. Successive ITU World Radiocommunication Conferences have taken into account the needs of WMO to ensure the availability and protection of radio-frequency bands for such atmospheric and other environmental observation tools as radiosondes, weather and wind profiler radars and spaceborne infrared and microwave sounders. This new version of the Handbook on Use of Radio Spectrum for Meteorology: Weather, Water and Climate Monitoring and Prediction has been jointly developed by experts of ITU-R Working Party 7C under the chairmanship of Mr. M. Dreis (EUMETSAT) of ITU-R Radiocommunication Study Group 7 (Science Services), and the Steering Group on Radio Frequency Coordination (SG-RFC) of the WMO Commission for Basic Systems (CBS), under the chairmanship of Mr. Eric Allaix (France). The Handbook provides comprehensive technical and operational information on current observation applications and systems and on the use of radio frequencies by meteorological systems, including meteorological satellites, radiosondes, weather radars, wind profiler radars and spaceborne remote sensing instruments. It is intended for the meteorological (i.e. weather, water and climate) and radiocommunication communities, including governmental institutions, industry as well as the general public. Mr. Petteri Taalas Mr. Houlin Zhao Secretary-General Secretary-General World Meteorological Organization International Telecommunication Union Use of Radio Spectrum for Meteorology: Weather, Water and Climate Monitoring and Prediction v TABLE OF CONTENTS Page FOREWORD ......................................................................................................................... vii INTRODUCTION ................................................................................................................. ix CHAPTER 1 – GENERAL STRUCTURE OF METEOROLOGICAL SYSTEMS ............ 1 CHAPTER 2 – METEOROLOGICAL SATELLITE SERVICE (MetSat) .......................... 9 CHAPTER 3 – METEOROLOGICAL AIDS SERVICE ..................................................... 21 CHAPTER 4 – METEOROLOGICAL RADARS ................................................................ 37 CHAPTER 5 – PASSIVE AND ACTIVE SPACEBORNE REMOTE SENSING FOR METEOROLOGICAL ACTIVITIES ........................................................................
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