GISdevelopment.net ---> AARS ---> ACRS 1990 ---> Water Resource Real-Time and all-weather Quasi-Real-Time Montoring System of Remote Sensing information on the flood dangerous state and losses Cao shahu The Remote Sensing Center of The Ministry of water Resources Beijing, China Abstract This paper introduces to the remote sensing information system for real-time or all weather quasi-real-time monitoring flood, which synthesizes the application of remote sensing (technique), communication (technique), and geographic information technique. It will be helpful for the headquarter of flood control to see the flood area over thousands kilometer away from the headquarter and understand the flood level and its change. Besides, the system can investigate the losses of flood submergence quickly by using flood control database. Thus the headquarter can make the precise judgment and take emergent measure to reduce the losses in the life and property of the people. Real-Time Monitoring System of Remote Sensing Information on the flood dangerous state and losses of the yellow river basin The composition of the System The system is composed of the following two subsystems----real time transmission subsystem of aerial images and level data of flood and flood-control Database of flood detention and storage area in the Yellow River Basin. Real - time transmission subsystem of aerial images and level data of flood consists of remote sensing plane, automatic measuring station of water-level, transition station of aerial images and level data, communication satellite and microwave relay station, receiving and recording station and processing center. Remote sensing plane is used to trace the flood of the yellow River. On the plane, high resolution TV cameras real-aperture (8mm) side-looking radar take the images of flood level-receiver receives level data from automatic measuring station of water-level, and transmitter sends the level data and flood images to Transition Station. Moreover communication line is equipped on the plane so that the position of plane and the state of flood can be timely reported and the communication connation can be continuously kept. The automatic measuring station of water-level, which consists of level sensor and level data transmitting device, monitors the level and its change of the test section. The transition station receives flood images and level data from the plane, and then put them into microwave communication lines and sends them to a communication satellite respectively. Receiving device of flood images and level data, microwave communication equipment, TV transformer and small satellite ground station are equipped in the transition station. The communication satellite and the microwave relay station are used to transmit flood images and level data real-timely and in long distance. The processing center real -timely receives, displays and records flood images and level data of the yellow communication lines, and put them into computer image processing system, which can process them and output the results. The equipment of the center include: receiving device which receives flood images of the Yellow River transmitted to Beijing by the microwave communication lines, satellite ground station which receives flood images and level data transmitted to Beijing by communication satellite relay, and transformer, display device, video recorder, computer image processing system and the like. The receiving and recording station has TV set and video recorder. Flood-control database of flood detention and storage area must be in advance established, so that the losses can be quickly calculated by using real -time transmission subsystem of flood images and level data when the Yellow River in flooded. A great amount of information about natural and social economics in flood-plain and detention and storage areas are digitized and put into computer. Special management software has been studied. The data of flood-control database include height, land -use state, settlement and social economic data, because height data are essential to determination of submergence scope and water depth and the data of land-use state, settlement and social economic data, because height data are essential to determination of submergence scope and water depth and the data of land-use state, settlement and social economics are necessary for calculation of losses. Height data are acquired by sampling from topographic maps (1:10,000) according to the grid of 100mx 100m. In order to acquire the newest land-use state data, we specially took aerial colour infrared images before the flood of this year, complied land-use state map (1:50,000) based on visual interpretation of them, and finally got land-use data by digitizing the land-use state map. Settlement and social economic data, which are generally point distributive, are collected by using topographic maps (1:5-0,000) and social economic investigation information concerned (lack in the data of factory-enterprises). The total flood-control data in this test are near 4,000,000. Moreover, we have studied the programs of data input, storage, revision retrieval, statistics, form composition and graphic display and output, etc. Introduction to the Test We got great successes in this test of the system on August 22, 1988. While the plane flys above the Yellow River, sensor takes flood images and level receiver receives flood level data from the automatic measuring station of water-level. Transmitter on the plane sends the remote sensing images and level data to Liutun transition, where they are divided in to two channels to be transmitted in long distance. In one channel, images and level data are transmitted to the satellite 5 of the International Communication Organization, and sent to Yungang communication satellite main station in Beijing by the satellite. After signals are enhanced, the Remote Sensing Center of the Ministry of Water Resources receives displays and processes them. Because of the limitation of signal-channel width of communication satellite used in this year, stationary images and level data of flood are transmitted to Beijing. In the other channel, flood images are transmitted to CCTV through the microwave communication lines of the Broadcasting and Television Department of Henan Province and the Post Ministry, and then are sent to the Remote Sensing Center of the Ministry of Water Resources through the microwave communication line from CCTV to the Ministry of Water Resources. When the images of flood in the channel are transmitted to Zhengzhou, the Television Station of images of flood in the channel are transmitted to Zhenghou, the Television Station of Henan Province televises them by the ninth frequency channel. Therefore, the Water conservancy Committee of the Yellow River can real-timely receive and record the flood images. The flood images transmitted to Beijing can be put into computer within 3 seconds. The images, which have been processed, can be output in hardcopy within 75 seconds. The submergence scope and losses can be retrieved in flood-control database by using level data or one village name on the flood boundary line, and submergence scope map and Chinese and English loss tables can be quickly output, thereby the level data of flood, submergence scope and losses can be quickly output, thereby the level data of flood, submergence scope and loses can be quickly provided to the flood-control command departments. The deference is 2.9 percent between the losses retrieved in flood-control database by using real-time flood image around Zhongwanzhuang and Outan one day of 1988 and ones investigated by the Water Conservancy Committee of Yellow River in the field of the same day we are satisfied with the result. All-weather and Quasi-Real-Time Remoter Sensing System for flood monitoring and flood control data base of the Jinjiang-Dongting lake region. All-weather and Quasi-Real-Time Remote Sensing System for Flood Monitoring. For the sake of flood monitoring possibly done at any time under any conditions a quasi-real-time and all-weather remote sensing system for flood monitoring was designed in 1989, upon the experience of the remote sensing application tests on flood-control of the Yellow river in 1988. This system is composed of airborne SAR, optical imaging, image transformation, image transmission and image and data processing. It is known that an airborne SAR allows 24 hours monitoring a day, whether it is fine or not, covering wide area at high flying speed. The films of data acquired can become films of image through optical correlation. The images from the films of image are laid together so that a mosaic showing a flooding river is obtained. With the radar imagery, which clearly shows the water body and the content of water in soil, it is easy to define the bound of a flood, therefore it is a very helpful tool for a flood-control commanding unit to make out the severe ness of the flood within a wide range. However, viewing that the process of producing imagery is too long, it is certainly not a real-time system for flood monitoring or a quasi-real-time system even. To increase its effectiveness, an image separator is developed, which can be mounted on front of the slit of the optical correlator. Not affecting optical imaging, the device allows the use of CCD camera to do the optical-electrical transformation of the separated imagery, and by a signal devise the transformation image signals can be turned into full TV signals for transmission and display. Thus, it gains a lot of time. Moreover, to identify the position of an object in the imagery received and displayed, maps of study area are put into a microcomputer by way of video camera, and display on screen. With the special software developed, the monitoring range and the transmission channel are overlaid on the map. To indicate on the map the transmitted image, a signal plane is designed, which can move synchronously on a given image channel with the display on another monitor. To test the performance of the system, we monitored the second flood peak on the night of August 11, every thing was carried out according to the planned time table. Transmission started only one hour and 5 minutes after landing, comparatively it is 13 hours ahead of that by conventional means. The transmitted imagery moreover was made 4-fold larger than the original, with topography, type and water conservancy profects etc clearly identifiable. The same good result was also obtained in the similar test carried out in the Jinjiang-Dongting Lake region. Flood-control Database of the Jinjiang-Dongting Lake Region In collection, vector digitization and raster digitization techniques were used to derive DTM data from topographic maps (1:10,000) of the test area, over 900 frames in all. After the vector-raster transformation densification of the collected data was done with computer, topographic height data with 50mx50m interval were obtained. Then, with the Landsat TM data recorded in tapes, the A/D data of the SPOT imagery and with the special software, automatic recognition and classification were carried out, in order to obtain the land use data on the 9 types of area-featured objects in the test area (such as irrigated land, arid land and forest). To secure the accuracy of the 7 line-featured objects (dam, road for example), vector technique was taken to extract the relative features out of the map including water conservancy maps and communication map; and after vector-raster transformation with the computer and superposition of them with the land-use data on the 9 types of area-featured objects, land-use state data of the whole test area were obtained. As for the acquisition of the data on settlement and social economy, to ponym dictionaries were first referred to define their names; after that, 1:50,000 topographic map were used to determine their positions. Then, height data were adopted to determine the height of those points which were then encode and put into the computer together with their social economic data obtained from investigation. For each settlement, generally there were 15 data items, With the names, attributes, fixed capital, annual output of industry and agriculture, and even the number of the rooms at the settlement fed into the computer, data on the settlement and social economy of the test area were obtained. In general, in the establishment of the flood-control database of the Jinjiang-Dongting Lake region, about over 90,000,000 data were processed and stored, which have basically met the requirements for the loss estimation. These, together with the developed software's for input, revision, inquiry and output, have laid sound foundation for future investigation of flood conditions in the area. Prospects of flood-control Remote Sensing The flood control remote sensing tests carried out in 1987, 1988 and 1989 have not only turned out great results but also displayed the potential and good prospects in suing remote sensing and GIS techniques against flood. We assume that a future remote sensing information system of practical value for real-time monitoring of flood should include the following two parts: A remote sensing plane with multi-functions. It has powerful non-stop flying capability, good enough to fly from Beijing to any part of the seven longest rivers in China, carry out the mission and fly back, and has all-weather flying capability. Aboard, all-weather SAR or an advanced photographic camera or a high resolution video camera can be changeably mounted, depending on the weather and work. In addition, there are such equipments such as: a hydrographic data acquisition system, a transmitting equipment that can transmit the collected data and the flood imagery to a communication satellite and a dual communication system that assures communication between the plane and the base. In the processing center there should be a set of computer image processing system, capable of receiving real-timely and processing at high speed all the data concerned with a flood. The system should have large external memories and more complete peripherals Besides, there also should be a set of receiving equipment in the center that receives the imagery from the Polar meteorological Satellite (PMS). About the operation with such a practical flood-control system, there are following presumptions: Constant monitoring of the water situation about the seven longest rivers during rainy season is to be done by taking advantage of the PMS imagery, so as to know where is flooded timely. A multi-function remote sensing plane will be dispatched to the flooded area discovered by the PMS to acquire imagery and level data and to transmit them to coruscation satellite, which relays them promptly to Beijing. The received imagery will be displayed and put into the image processing system for geometric correction and flood boundary attraction. With the extracted boundary data, the losses caused by the flood can be figured out by the flood-control database. Using the analysing model in the database, which has an important role to play in flood-control planning, regulating and preview, we can make greater contributions to our country in this field.