Ambulance Management System Using GIS

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Master Thesis in Geoinformatics

Ambulance management system using GIS

By

Imtiyaz Pasha

Supervisor & Examiner: ProF. Dr. Åke Sivertun

Department of Computer and Information Science Linköping University SE-581 83 Linköping, Sweden

LINKÖPING 2006

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Abstract
For emergency service providers, giving their service in least time shows their best performance. Emergency hospitals will be at their best if the ambulance reaches the site in Golden hour where life of injured persons can be saved. Ambulance uses the road network to reach the accident site. Today there are many GIS based systems being developed for routing of ambulance using GPS and other real-time technologies. These systems are useful and play a major role in solving the routing problem. But now roads are so congested that it difficult for the Ambulance drivers to travel and reach the accident.

In this thesis present study area is studied and problems faced by emergency service providers on road network are identified. In this thesis GIS/GPS/GSM based prototype system has been developed for routing of ambulance on road network of Hyderabad city (AMS). This prototype is designed such that it finds the accident location on the road network and locates the nearest ambulance to incident site using the real-time technologies (GPS/GSM). AMS creates the fastest route from nearest ambulance to accident site, and from there to nearest hospital. Congestion on roads during peak hours is considered, and the fastest route on both major and minor roads is created. In this thesis AMS user interface has been developed using VBA, ArcGIS (network analyst). This Ambulance management system has been developed using software engineering model rapid prototyping model and has been evaluated by GIS users.

Keywords: GIS, GPS, GSM, Ambulance management system (AMS), Network analyst

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Acknowledgements

First of all I would like to thank my supervisor Dr. Sivertun, Department of computer science (IDA), for all his help with this thesis. I have learnt a lot from Dr. Sivertun, how to work hard and getting right results. Dr. Sivertun always has time for my questions and his comments on my thesis have been valuable. I am also thankful to my course coordinator Jalal Maleki. I would also like to thank my colleagues for providing me good suggestions. I am thankful to Andhra Pradesh authorities for providing Hyderabad data. I am thankful to Dhanunjaya Reddy for providing the Hyderabad city digital data, which I have used in my thesis. I wish to thank my friends for supporting me in many ways. Last but not least, I am deeply grateful to my family and my uncles M.A Quyyum and M.A Huyyum who supported me in many ways. Linkoping, May 2006 Imtiyaz Pasha

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Table of Contents Introduction ....................................................................................................................................8
1.1 Motivation .......................................................................................................................................................... 8 1.2 Problem Statement ............................................................................................................................................ 8 1. 3 Purpose/Goal..................................................................................................................................................... 9 1.4 Limitations ......................................................................................................................................................... 9 1.5 Thesis Outline .................................................................................................................................................. 10

Theoretical Frame ........................................................................................................................11
2.1 Study Area ....................................................................................................................................................... 11 2.1.1 Population.................................................................................................................................................. 11 2.1.2 Cause for huge traffic flow ........................................................................................................................ 12 2.1.3 Historical fact ............................................................................................................................................ 12 2.1.4 Increase in Vehicles................................................................................................................................... 14 2.1.5 Number of accidents in Andhra pradesh.................................................................................................... 16 2.2 GIS.................................................................................................................................................................... 16 2.2.1 GIS role in Transport................................................................................................................................. 16 2.2.2 Database role in GIS-T .............................................................................................................................. 17 2.2.3 GIS and transport related fields of applications (GIS-T) ........................................................................... 17 2.3 ArcGIS ............................................................................................................................................................. 19 2.3.1 ArcMap...................................................................................................................................................... 19 2.3.2 Network Analyst........................................................................................................................................ 20 2.4 Global Positioning System .............................................................................................................................. 22 2.4.1 Fleet management...................................................................................................................................... 23 2.4.2 Data collection and mapping ..................................................................................................................... 24 2.4.3 Incident management................................................................................................................................. 25 2.4.4 Vehicle navigation..................................................................................................................................... 26 2.4.5 Transport of hazardous Materials .............................................................................................................. 27 2.4.6 Limitations of GPS .................................................................................................................................... 27 2.5 Global System for Mobile Communication (GSM) ...................................................................................... 27

Methodology .................................................................................................................................31
3.1 Ambulance Management System prototype using GIS/GPS/GSM........................................................... 31 3.1.1 Data Collection .......................................................................................................................................... 33 3.1.2 GIS database.............................................................................................................................................. 33 3.1.3 Analysis (GIS/GPS/GSM) ......................................................................................................................... 37 3.1.4 AMS information for decision making...................................................................................................... 39 3.2 AMS User interface Development.................................................................................................................. 43 3.2.1 Mechanism ................................................................................................................................................ 43 3.2.3 Nearest closest facility............................................................................................................................... 44 3.2.4 Rapid prototyping model for AMS............................................................................................................ 44 3.2.5 Software development for AMS of Hyderabad City ................................................................................. 45 3.2.6 AMS user interface flow Chart.................................................................................................................. 46 3.2.7 AMS Input Sources ................................................................................................................................... 48

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3.2.8 Themes for Analysis.................................................................................................................................. 48 3.2.9 Designed Interface of AMS ....................................................................................................................... 48 3.2.10 Database Design of AMS user interface.................................................................................................. 52

Usability Test (Evaluation)..........................................................................................................54
4.1 User Test........................................................................................................................................................... 54 4.2 Followed Paradigm.......................................................................................................................................... 54 4.2.1 Observations .............................................................................................................................................. 54 5.2.2 Interviews .................................................................................................................................................. 55 5.2.3 Questionnaires ........................................................................................................................................... 55

Results ...........................................................................................................................................57 Discussion ......................................................................................................................................70
6.1 Conclusion........................................................................................................................................................ 70 6.2 Future Work .................................................................................................................................................... 71

Bibliography .................................................................................................................................72 Appendix .......................................................................................................................................78

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List of Figures
2.1 Road network of Hyderabad city……………………………………………………………..13 2.2 Hyderabad police and fire station…………………………………………………………….13 2.3 Traffic jams are a familiar sight in the city…………………………………………...............14 2.4 Functionalities of ArcGIS9.1 network analyst extension…………………………………….21 2.5 Global Positioning System for Vehicle tracking System…………………………………….23 2.6 Road map of GPS tracking…………………………………………………………………...24 2.7 Basic modules (building blocks) for a location and navigation system……………………...26 2.8 Hazmat telegeomonitoring……………………………………………………………………28 2.9 GSM/GPS/GIS based System Architecture…………………………………………………..28 2.10 Modular Mobile Dispatching System (MMDS)…………………………………………….29 2.11 AMBULANCE system architecture………………………………………………………...30 3.1 Information flow after accident occurred on road network…………………………………..31 3.2 Methodology for AMS using GIS……………………………………………………………32 3.3 GIS database for analysis in ArcMap9.1……………………………………………………..34 3.4 Database use in AMS………………………………………………………………………...36 3.5 GIS/GPS/GSM technology…………………………………………………………………..37 3.6 AMS Architecture……………………………………………………………………………38 3.7 If accident site didn’t find than………………………………………………………………40 3.8 Telematics Applications……………………………………………………………………...42 3.9 Critical Time/ Space Elements………………………………………………………………43 3.10 Rapid prototyping model of AMS………………………………………………………….45 3.11 AMS flow chart…………………………………………………………………………….47 3.12 AMS Interface model……………………………………………………………………....51 3.13 OOGIS architecture of AMS user interface………………………………………………..52 4.1 Result from Evaluation……………………………………………………………………..55 5.1 To identify the accident…………………………………………………………………….58 5.2 To identify the ambulance locations……………………………………………………......59 5.3 To identify fastest route from all ambulances to accident site……………………………….60 5.4 To identify fastest routing ambulance to the accident………………………………………..61 5.5 To identify fastest route to the hospital……………………………………………………..62 5.6 Multiple accidents Scenario I……………………………………………………………….63 5.7 Multiple accidents Scenario II……………………………………………………………….64 5.8 During peak hours situation I……………………………………………………………......65 5.9 During peak hours situation II……………………………………………………………….66 5.10 During peak hours situation III……………………………………………………………..67 5.11 During peak hours situation IV……………………………………………………………..68 5.12 During peak hours situation V………………………………………………………………69

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List of Tables
2.1 Population of Hyderabad every decade………………………………………………………11 2.2 Composition of traffic flow in Major Corridors……………………………………………...15 2.3 Bus Fleet and No. of passengers carried per day……………………………………………..15 2.4 Number of Accidents in Hyderabad………………………………………………………….16 2.5 ArcGIS extensions……………………………………………………………………………20 3.1 AMS database…………………………………………………………………………….33-34 3.2 AMS Menus………………………………………………………………………………49-50 3.3 AMS Tools………………………………………………………………………………..50-51

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Chapter 1

Introduction
1.1 Motivation
In today’s traffic world, ambulance plays a major role when accident occurs on the road network and need arises to save valuable human life. Transportation of a patient to emergency hospital seems quite simple but in actual it is quite difficult and gets more difficult during peak hours. Hyderabad is a growing metropolitan city with rapid increase in the number of vehicles, traffic jams, lack of footpaths and unsafe roads for people to walk or to cross. Advanced Traveller Information System (ATIS) by (Kumar .P et al 2003) for Hyderabad city is really a great work indeed, but there is no Advance travelling system for ambulance movement. This ATIS is developed using ArcView3.1, Network Analyst 1.1b and Avenue programming language. It can be re-designed using more advanced GIS technologies and programming languages. National Center of Immediate Assistance (EKAB) [Derekenaris .G 2000] has designed GIS/GPS/GSM (G3) system for the ambulance management. G3 system is used to track low flying aircrafts and vehicles on a digital map in real-time. This G3 system was a combination of GPS, GIS, and GPRS (which is based on GSM technology) [Lin et al 2003]. These technologies really motivated to be implemented in the more densely congested roads of Hyderabad city. In this thesis GISbased efficient ambulance routing system is developed using ArcGIS9.1 (Network Analyst extension), real-time positioning techniques (GPS/GSM) and VBA. This proposed prototype model will try to solve the routing problem of Ambulance (ambulance- accident locationemergency hospital).

1.2 Problem Statement
Metropolitan areas across India are facing the problem of increase in congestion. Every year due to traffic congestion millions of hours of vehicle delay increases in fuel consumption and environmental pollution. Recurrent congestion is due to two major reasons. • • High levels of traffic demand during peak travel hours cause reduction in the available roadway capacity. Traffic accidents and other incidents cause an unanticipated reduction in road capacity.

Traffic incidents are main cause for the problem of recurrent congestion especially when they occur during peak hours. Incidents occur randomly during peak hour which may contribute to an increased occurrence of certain types of traffic incidents [Maas et al 1998]. Different approaches to solve problem of recurrent congestion have been proposed and are being implemented such as road capacity expansion can alleviate congestion problems but may not be a solution that is sustainable in the long run [Reddy J.S., 2006]. In Hyderabad city many flyovers have been built in the last few years, but didn’t help in reducing traffic congestion. Construction of flyovers at Secretariat, Narayanaguda and Masab Tank were major cause of obstructions to the free flow of vehicles [Reddy J.S., 2006]. With the present growth rate the vehicular population of Hyderabad is expected to cross 20 lakh (2 million) by 2010, having serious implications on emissions and 8

quality of life [Reddy J.S., 2006]. Andhra Pradesh government took loans from World Bank and roads were widened but didn’t help in a few places, lack (or disappearance) of footpaths resulted in use of personal vehicles even for short distances by the commuters. It is difficult for people to cross the roads during peak hours because more vehicles are moving on the roads. If a vehicle travels from origin to destination during peak hours it takes longer time compared to normal time. In Hyderabad city there are three Emergency service providers of the state government i.e. police, hospitals and fire bridges. Most of the emergency hospital ambulances are equipped with paramedics, even though they are unable to reach the incident site because of huge traffic at junctions. Once the ambulance gets struck in traffic, it takes more-time to reach the incident and it is obvious what happens to the patient till the ambulance reaches? Due to lack of verification sometimes ambulance driver is unable to find the accident site as reported. Location, identity, time and activity have been identified as primary context types for characterizing the situation of an accident [Arrington& Cahill 2004]. Andhra Pradesh transport authorities have detailed information on current features of the road network such as location, type, width, curvature, altitude, slope etc, and will be stored in databases. This database must be updated frequently so that it should be practically feasible. Dynamic data relevant to route performance includes details such as current traffic flow or speed, weather, road surface conditions and variations in road usage patterns due to events such as accidents, road maintenance or sports fixtures [Arrington& Cahill 2004] should be provided to emergency service providers. This database and GIS together can be helpful in finding the accidents on the road networks and the shortest & fastest route to the accident site.

1. 3 Purpose/Goal
The main objective of this thesis is to build a GIS based prototype for the ambulance management when an accident occurs on Hyderabad road networks. This Ambulance Management System (AMS) is an integration of GIS (ArcGIS9.1 network analyst, GPS/GSM) used for solving the routing and accident location problems during normal & peak hours such as. 1) To identify the accident on the road network. 2) To identify the ambulance locations on the road network in real-time using GPS coordinates. 3) To find the fastest routes through which all the ambulances can reach the accident site. 4) To find the ambulance which can immediately reach the accident site as compared to other ambulances is analysed. 5) After finding fastest route from the nearest ambulance to the accident location then the fastest route from the accident site to the nearest hospital is calculated. 6) If more than one accident occurred on the road network, we have to find the fastest routes through which ambulances can travel to reach all the accidents. 7) To find the fastest routes from all the accidents to reach the hospital immediately. 8) During the peak hours roads are congested, how ambulances should travel.

1.4 Limitations
AMS (Ambulance Management System) will provide speedy transportation of a patient when an

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accident occurs in Hyderabad city. AMS can be used for city wide, if the whole city street network and hospitals database is available. This prototype for ambulance management is studied on a small geographical area of Hyderabad city due to lack of data. This system can be developed as whole model, but we need sufficient funding from Andhra Pradesh state government. According to (Kumar P et al 2003), Intelligent Transportation System (ITS) should be cost effective, efficient and at the same time it should be compatible with present level of development in the related fields. Intelligent Transportation System (ITS) for life saving costs more to government than whom should be responsible. Private sector companies should come forward to have a part in development of the country.

1.5 Thesis Outline
The theory on present study area Hyderabad city uses Geographical Information System (GIS), Global Positioning System (GPS) and Global Communication System (GSM) for vehicle location system is described in Chapter 2(theoretical frame). In this chapter, research work in ambulance location system using GIS is discussed in detail. Methodology of Ambulance Management System (AMS) and its working prototype system design is described in chapter 3. The detailed working design and working of Ambulance Management System (AMS) is also described. Usability of the Ambulance Management System (AMS) user interface is tested by GIS users and their comments are described in chapter 4. The results obtained from AMS are described in chapter 5. In chapter 6, description about the future work related to AMS and what we concluded from the ambulance management system.

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Chapter 2

Theoretical Frame
2.1 Study Area
Hyderabad is a capital city of Andhra Pradesh (India) and also India’s fifth largest city .It has been the capital of the state of Andhra Pradesh since 400 years [Ali Akhter 2004]. It is well known as hub of information technology and the city of the future. It is growing along the highways which connect the city to Mumbai, Delhi, and various cities& district headquarters respectively. Thus urban-industrial-transportation development seems to go hand in hand in these areas and this is a significant post independence phenomenon [Ali Akhter 2004]. Hyderabad city is located in the centre of the Deccan Plateau at an average height of 540 meters (1760 feet’s) above mean sea level. Hyderabad has Nagpur city on the North, Bangalore city on the South, Vishakhapatnam city on the East, Mumbai city on the West beside many other cities around. The city is located at 17° 20’ North latitude and 78° 30’ East longitude, covering an area of 240 SqKms, at present city consists of 35 municipal wards including 12 wards of Secundrabad [Ali Akhter 2004]. Musi River is a tributary of river Krishna and passing through centre of the city dividing the city into north Hyderabad and south Hyderabad. 2.1.1 Population Hyderabad city was the fifth largest metropolis of India with a population of 5,434,347 according to 2001 census. The gradual increase in population of Hyderabad is mentioned below [Ali Akhter 2004]. Year Population 1901 0.448 millions 1911 0.502 millions 1921 0.406 millions 1931 0.447 millions 1941 0.739 millions 1951 1.28 million 1961 1.429 million 1971 1.796 million 1981 2.759 millions 1991 4.34 millions 2001 5.43 millions Table 2.1: Population of Hyderabad every decade Due to rapid growth of urban sprawl and increase of population resulted in the following facts. • Deterioration of infrastructure facilities.

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• • • • • • • •

Loss of productive agricultural lands. Loss of green open spaces. Loss of surface water bodies. Depletion of groundwater aquifers zones. Causing air pollution. Contamination of water. Health hazards Micro-climatic changes.

To solve this problem we need accurate data at regular intervals about urban land use, environment, sprawl, infrastructure and resources. 2.1.2 Cause for huge traffic flow Hyderabad city is divided into two parts (old city and new city). A large number of research and training institutions of national importance are located mostly outside the old city, and though the Osmania general hospital is located in old city, there is a gross inadequacy of health facilities [Ali Akhter 2004]. Hospitals and educational institutions located outside old city results in movement of people between old and new city to get these facilities, and due to which traffic flow on roads increase. During peak hours 9AM-11AM in morning and 4PM-8PM evening there is a huge traffic movement on road networks. Not only traffic increases but also inhabitants living in old city also facing difficulties. 2.1.3 Historical fact Old city being unplanned and oldest due to which roads are narrow and most of the road side rules are violated. Police & Fire stations are not properly located in the Hyderabad city as shown in figure 2.2. Hyderabad city was founded by Mohammed Quli Qutub Shah in 1591 AD. Historical aspects and geography of the urban development Hyderabad city has been such that rapid development has taken place in a few areas on one hand and on the other hand few areas have declined since decades, especially the old city area [Ali Akhter 2004]. City was built to provide shelter for about 5 lakh population but now it is increased to 50 lakhs. In the present situation emergency service providers were unable to provide services to current population.

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Figure 2.1: Road network of Hyderabad city

Figure 2.2: Hyderabad police and fire station [Ali Akhter 2004]

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2.1.4 Increase in Vehicles Hyderabad is a metropolitan city with vast increase in the number of vehicles, traffic jams and lack of footpaths. In Hyderabad, roads are unsafe for people who would like to walk or to cross roads. The transport authorities have given more importance to flyovers rather than to give more importance to efficient public transport. Due to unplanned growth of the city and migration of people from rural areas, districts and inefficient public transport system has resulted in an unpleasant situation for traffic in the city. In the last two decades the number of vehicles has grown enormously [Reddy J.S., 2006]. In Hyderabad most of the people depend on personal vehicles for transport due to these traffic jams and choking of streets has become quite common.

Figure 2.3: Traffic jams are a familiar sight in the city [Dr. Reddy S. J -2006]

At present there are about 11 lakhs (1.1 million) vehicles in the city [Reddy J.S., 2006]. There is a high growth rate in two-wheelers and cars during the last five years of the last decade with an increase rate of about 10% per year. In Hyderabad more than 80% of the vehicles are twowheelers (mostly 2-stroke engines) producing a bulk amount of unborn hydrocarbons and carbonmonoxide. About 10% vehicles comprises of trucks, buses, taxis and 3-wheeler, which are mostly used for daily transportation. The transport vehicles used for commercial purposes (about 90000) normally runs for more than 100 kms per day and most of them are using diesel as fuel. More than 50% of these vehicles are reported to be not eligible or unfit for PUC (Pollution under Control) certificate, as they are older than 15 years. The average life span of a vehicle is six years, which travels about 300 km per day and there is no way to use these kinds of vehicles after they travel for 500,000 kms. Average number of vehicles travel on roads contributes a major change to mode of travel on city roads. Travelling modes of last two decade are shown in below table.

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Mode of Travel Buses Scooters/ Motor cycles Cars Auto rickshaws Bicycles Others

Composition of traffic flows During-1986(%) 2 18 4 6 42 28

Composition of traffic flows during-1998(%) 3 50 14 18 10 5

Table 2.2: Composition of traffic flow in major Corridors [HATS – DB I-2002I]

Andhra Pradesh State Road Transportation (APSRTC) buses are the major transportation mode for regular education trips and work. Table below shows that buses remain static over the years though the bus fleet continuously increases from time to time.

Sl.No

Year

Bus Fleet

Occupancy

1 2 3 4 5 6 7

1995-96 1996-97 1997-98 1998-99 1999-2000 2000-2001 2001-2002

2018 2122 2217 2328 2425 2480 2605

74 75 69 70 63 58 59

No of passengers carried per day in Millions 2.981 3.177 3.054 3.253 3.050 2.872 3.068

Table 2.3: Bus fleet and No. of passengers carried per day [HATS – DB II-2002, APSRTC]

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2.1.5 Number of accidents in Andhra pradesh
GOVERNMENT OF ANDHRA PRADESH TRANSPORT DEPARTMENT Road Accidents Particulars Number of Accidents Name of the District / City 2005 2004 2003 2002 Hyderabad 3042 3802 3526 3062 Rangareddy 569 479 984 2839 Cyberabad 3107 3078 2453 0 Mahaboobnagar 1355 1420 1180 1256 Nalgonda 1958 1770 1519 1558 Nizamabad 1367 1346 1564 1520 Medak 1276 1490 1430 1252 Warangal 1591 1661 1251 1582 Khammam 1663 1743 1316 1386 Karimnagar 1522 1584 1477 1450 Adilabad 1344 1487 1406 1365 Kurnool 1400 1438 1145 1167 Cuddapah 1357 1243 973 1100 Anathapur 1127 1126 1001 1066 Chittoor 1909 2018 1809 1830 Guntur 1727 1668 1438 1301 Nellore 1033 1284 849 1137 Prakasham 998 845 751 693 West Godavari 1607 1493 1345 1302 East Godavari 2304 2033 1854 1989 Krishna 1180 1109 868 860 Vijayawada 1172 1306 1239 1081 Visakhapatnam 994 912 1079 1106 Visakhapatnam 1067 981 846 837 Rural Vizayanagaram 908 883 776 810 Srikakulam 762 738 747 584 Total Number of Persons Killed 2005 2004 2003 2002 2001 344 448 496 420 404 181 143 318 810 692 852 875 711 0 0 599 592 480 515 504 717 835 515 572 500 317 323 290 309 251 535 497 554 501 398 397 421 366 380 317 448 419 360 386 252 416 403 406 427 340 331 307 267 296 198 423 373 328 406 362 420 387 294 327 235 399 417 341 371 317 653 660 545 502 433 555 749 476 432 388 394 384 316 303 308 349 355 296 303 291 511 517 499 513 427 634 487 450 517 477 343 302 307 284 292 282 214 241 267 174 221 239 203 168 181 338 207 210 280 207 212 Number of Persons injured 2005 2004 2003 2002 2001 3448 3958 3361 2785 2307 879 767 1289 3595 3044 2734 3208 2728 0 0 2103 2230 1830 2007 1915 3309 2707 2291 2422 2264 2330 2255 2862 2512 1606 2317 2710 2426 2208 1780 2423 2606 2301 2432 1992 2456 2909 1889 2180 1785 2208 4061 2088 2016 1501 2203 2492 2202 2399 1746 2299 2429 1649 1770 1331 2166 1869 1425 1652 1085 1878 1942 1773 1743 1442 2710 2938 2344 2413 1883 2238 1966 1719 1672 1324 1613 1952 1624 1687 1222 1207 966 957 1034 779 2149 1915 1594 1566 1200 2713 2471 2298 2317 1947 1830 1605 1183 1074 1059 1136 1346 1261 1191 796 1149 1158 1139 1055 1026

2001 2609 2531 0 1095 1426 1216 1093 1350 1135 1136 1056 965 853 841 1485 1078 984 605 1017 1716 826 743 1054 774 714 600

202 189 183 1611 1476 1163 1123 1069 199 161 160 1329 1421 1079 1179 1057 219 164 164 1228 1082 1002 776 771

38339 38937 34826 34133 28902 11076 11046 9679 9523 8248 53666 56439 47477 46808 37931

Table 2.4: Number of accident A.P [Misra Ajay 2005]

2.2 GIS
2.2.1 GIS role in Transport Geographical Information System (GIS) is used for the storage and analysis of spatial information. GIS gives more emphasis on analysis of geographic information, in contrast with other graphic or management systems more directed at the representation of geographic data or its storage [Cowen, D.J 1988]. Today different disciplines use Information Technology(IT) to 16

process the geographic information (remote sensing, geography, civil engineering, cartography, topology, geodesy, photogrammetry, ecology, architecture, computer science etc) [Pons & Perez 2003].Transport networks are used for movement of people, goods, and energy. The features such as form, efficiency and capacity of these networks make an impact on our quality of life and improve our perception of the world. When GIS is applied to transport, this is more than just a sphere of application of their generic functionality [Thill 2000]. L.Downey, Deputy Secretary for Transportation said “We see the geographical Information Systems as a real opportunity to unify transportation planning with the vast data processing capabilities inherent to today’s technology” and also Xu(2000) said “telematic products and services for individual means of transport are based on the integration of digital maps, RDS/TMC ( radio data systems/ traffic message channels) for the transmission of traffic data, GPS(Global Positioning Systems) and GSM( Global System for Mobile Communications) for the transmission of travel data, and mobile telephone communications and other additional sensors are needed to collect travelling information in real-time”. 2.2.2 Database role in GIS-T Creating spatial databases for GIS based transportation is one of the most costly tasks from perspective of economy and time. The steps are followed to create geographic database [Pons & Perez 2003]. • • • • Topographic base maps have to be created for the transport infrastructure. Thematic attributes are compiled, Providing information on the traffic flows and on the transport infrastructure carried by the latter. Large scale information is needed for transport and the real-world object attributes vary continuously over the course of time.

GIS based transportation data is collected from different sources such as GPS, topography, photos, remote sensors, etc. The three important components are used for processing of information [Pons & Perez 2003], and any delay in its development results in complex matter. Locational component: the position of the data within a geographic space Thematic component: the type of geographic attributes to be found in a certain place Temporal component: the thematic aspect of a location at a given time With the incorporation of GPS (Global Positioning Systems), video logging, remote sensors, signal communication systems, and cellular telephones (GSM, VHF) into GIS, geo-localization techniques are undergoing a big revolution [Farrell & Barth 1999]. 2.2.3 GIS and transport related fields of applications (GIS-T)

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Geographical Information System (GIS) is applied to three major fields of transport [Pons & Perez 2003]:

1) transport planning : Geographical Information System (GIS) is used in accessibility studies, multimodal transport analyses, integral transport planning, assessing the environmental impact of new infrastructure policies, pollution control, risk planning and management, construction of new roads 2) fleet and logistical management: Geographical Information System (GIS) is used in route planning of car navigation system, metrological hazard control, traffic control, passenger assistance system, vehicle fleet control, emergency management 3) management of infrastructure: Geographical Information System (GIS) is used in road and motorway management, railway network management, airport management. Geographical Information System (GIS) is used for modelling of road networks offering algorithms to analyze and find the shortest or minimum route through a network. GIS can be used to calculate distance between sets of origin and destination, whereas location-allocation functions determine site locations and assign demand to sites. Street addresses can be converted to map coordinates (address geocoding) [G.DereKeneris et al 2000]. These capabilities of Geographical Information System’s (GIS) to analyze spatial networks enable them to be used as Decision Support Systems for directing and routing of vehicles [M.D Crossland et al 1995 & Keenan, P., 1996, 1997]. Data regarding Spatial position of ambulances, the distribution of incidents occurring in the past and distribution concerning road traffic will be very useful for the routing of ambulances in future. Data concerned to events such as road works or political/public demonstration also affects road traffic will be available from the municipality or the police. Furthermore, data concerning hospitals, ambulances, and their personnel will be stored in DBMS and used by the GIS whenever it is necessary. GIS is mostly employed today in operational research as a one way data feeder for mathematical models [Erkut E 2001] and successfully provides distance and time for their emergency services districting and location problems. The complexity of Arc routing problems can be solved using better integration of the mathematical formulation and resolution into the available GIS data model. The increase of GIS usage in transportation(GIS-T) has brought new paradigms in transportation planning such as the desegregation of the spatial locations but some challenges remain about the storage of the temporal data as the within applications[Goodchild MF 2000]. A graphical user interface allows displaying and manipulating graphical objects; data storage and processing allows an eased interaction with the mathematical optimizers. Different objectoriented modelling languages provide libraries of .dll files (tools) for efficient interaction of 18

different geographical data processing for the vehicle routing. However, the efficiency of a combined use of GIS, GPS, and a modelling language relies on the capacity to handle the huge amount of data related to the problem [Marzolf Fabien et al 2005]. Usually roads are monitored by patrol vehicles of police and Road Transportation Corporation (RTC). The aim of this road network monitoring is to detect various incidents occurring on it immediately so this activity could be planned very carefully. However, due to numerous incidents that call for the patrol to quit its planned route and move to the incidents location, most of the monitoring routes are not completed and the following ones have to be re-planned constantly [Marzolf Fabien et al 2005]. A bridge has been built between two distinct fields which allowed the use of operational data within robust and powerful mathematical algorithm to produce solutions and satisfies the operational constraints and the human requirements. Various forecasting methods including historical profile approaches, neural networks, non- timeseries models, traffic simulation models, parametric regression models and dynamic traffic assignment models are being developed by researchers of intelligent transportation system (ITS). One of the most critical elements of intelligent transportation system (ITS) is forecasting the travel time. In fact noble idea is extremely difficult to accomplish due to the complex nature of traffic networks [Keenan, P., 1998]. Detecting future travel time depends on features of the traffic networks including, speed, traffic flow, incident and queue.

2.3 ArcGIS
Organisation uses Geographical Information System (GIS) to obtain better information for better decision making. GIS presents the real-world objects on map and easy to use spatial tools for performing the most complicated task. In our real-world spatial objects are presented in different ways. In Geographical Information System, spatial objects are represented as point, line and polygon. ArcGIS is GIS software which belongs to ESRI software solutions. In ArcGIS desktop, there are three main applications of our interest ArcMap, ArcCatlog and ArcToolbox. ArcMap: This application is used to explore, analyze both spatial and non-spatial data. ArcCatlog: This application is used to manage spatial data ArcToolbox: This application contains tools to perform GIS tasks. 2.3.1 ArcMap ArcMap is the ArcGIS application used to perform the following task with geographical data. • To perform analysis • Explore and edit • Create maps, graphs and reports, etc The ArcMap working model consists of the map display area, table of contents, number of toolbars and menus for working with map and its attribute data. ArcGIS extensions allows GIS

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users to expand the functional capabilities of ArcView, ArcEditor, and ArcInfo with specialized GIS tools for raster geoprocessing, three-dimensional visualization, geostatistical analysis, etc.

Extension ArcGIS 3D Analyst ArcGIS Geostatistical Analyst

Use 3-dimensional visualization and analysis Statistical tools and models for data exploration, modelling and probabilistic mapping Routing closest facility, and service area analysis Automatic schematics generation for ArcGIS Advanced raster GIS analysis Integrated survey management for ArcGIS Time-based data visualization and analysis

ArcGIS Network Analyst ArcGIS Schematics ArcGIS spatial Analyst ArcGIS Survey Analyst ArcGIS Tracking Analyst

Table 2.5: ArcGIS extensions 2.3.2 Network Analyst ArcGIS Network Analyst is a powerful extension for routing purpose and used for making network-based spatial analysis such as [Elizabeth Shafer 2005]. • • • • • • • • Point-to-point routing Drive-time Analysis Route directions Shortest path Optimum route Origin destination Closest facility Service area definition

The main key features are routing (Multipoint routing, time windows supported on stops and travelling salesperson), service areas (Complex polygon generation, allocation across networks), closest facility (fixed and mobile asset routing, emergency response) and driving directions (expandable inset maps, Auto generation capability). Network Analyst will benefit the organisations like transport, public safety, local government, business and health care.

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ArcGIS 9.1 contain some of the improved functionalities, which are note available in old versions [Elizabeth Shafer 2005]. • To create multipart turns and global turn impedances • To create dynamic barrier (where vehicle can’t pass) • To create Complex (multimodal) network. • Time windows to show stop duration on stops within routes • To create u-turn restrictions and curb approaches for stops • To create large network • Network data sets can be geodatabase, shape file or SDC (smart data compressed) • Provide OD (Origin-destination) matrix functionality • To solve Custom problem (customer solver) • More advanced attribute data model for network impedances • Capability of geoprocessing tools, scripting and models • User specified directions setup wizards and their own customization Network analysis for optimal path routing and finding the best route between two or more points is based on distance, effort, time, or another measure. Optimal path routing is often used for routing emergency response vehicles [Allan & Gifford 1997]. Network Analysis extension of GIS is used to build an immediate, rapid and efficient emergency medical transport system for Middle East Technical University (METU) Emergency Service, Ankara, Turkey. It is called as AML (Ambulance Management Logistic) [Gülden et al 2004]. This study shows that Emergency transport system with a GIS extension Network Analysis shortens the delivering time and reduces the harm to patient to the lowest level. To avoid terrorist attack at Ericsson Stadium, ArcView’s extension Network Analyst is used to examine, plan and response of emergency resources in the California city. Some of the results from ArcView’s extension Network Analyst are as fallows [Elizabeth Shafer 2005]. • Closest Facility function to locate the emergency hospital and fire station closest to the stadium • Best Route function to model the best route from each trauma hospital to the stadium • Best Route function to model the best route from Charlotte Fire Station #13 located at 4337 Glenwood Drive to Ericsson Stadium and an alternate route that avoids Thrift Road

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Figure 2.4 Functionalities of ArcGIS9.1 Network Analyst Extension [Elizabeth Shafer 2005]

2.4 Global Positioning System
Global Positioning System (GPS) is a developing technology used to locate an accurate position on earth using satellite signals. Today GPS is used in different industries as a decision making tool. The development of GPS technology was started with TRANSIT system, the first satellitebased system was called transit, which came into existence in 1964. TRANSIT system had no timing devices on the satellites and the time took by the receiver to calculate its position was about 15 minutes. In the early 70's, the United States military began a program that would later be known as the NAVSTAR (Navigation Satellite Timing and Ranging System) GPS program [Mintsis. G et al, 2004]. NAVSTAR was actually used in military positioning, navigation and weapons aiming system. The information regarding the speed (dx/dt, dy/dt, and dz/dt) of vehicle, ship etc. is also obtained all over the world at any time, and in any climatic conditions [Mintsis. G et al, 2004]. The life span of each GPS satellite is 7.5 years. GPS receiver can be hand carried or installed on airplane, ship, buses, submarines, car and trucks. Global positioning system (GPS) receivers detect, decode, and process satellite signals to know the real-time position. The typical hand-held receiver is about the size of a cellular telephone, and the newer models are even smaller weighed only 28 ounces [Jason Dykes] Global Positioning System (GPS) applications are nowadays widely used in different scientific fields such as topography, geodesy, hydrography, photogrammetry, transportation etc [Mintsis. G et al, 2004]. Transportation of people and goods from one place to another plays a vital role in every aspect of the country’s economy. In India use of GPS/GIS technology in road and railway transportation can improve the efficiency of operations while at the same time it can make contribution to safety natural disasters and man-made disasters. GPS/GIS applications in the land transportation system are divided into four main categories that are as follows [Mintsis. G et al, 2004]. 1. Vehicle fleet management 2. How GPS use in Data collection and mapping. 3. Incident management

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4. Vehicle navigation systems 2.4.1 Fleet management GPS is used to provide information such as 1. Locating the nearest ambulance to the accident area. 2. Locating the nearest Police jeep to the crime accord area. 3. How much time a bus or train take to reach the station and how far it is from the station These kinds of systems are known as AVL (Automatic Vehicle Location) systems [Mintsis. G et al, 2004]. The real time data collected from GPS was spatially analysed using GIS. The accurate position of each vehicle is known by using spatial information. There are some problems with GPS based AVL, such as in urban areas big buildings obstruct the satellite signals. The GPS receivers receive poor quality of signals. Adding additional sensors with GPS devices can solve this problem. The three taxi companies in Singapore implemented the GPS-based Automatic Vehicle Location and Dispatching Systems (AVLDS) [Liao Ziqi 2003]. Each taxi is installed with a GPS receiver, antennae and a transmitter. The AVLD identifies the nearest taxi to a customer and also determine its route and location with coordinates of longitude and latitude. All taxis which were near to a customer offered a job via mobile data communications. When one of the drivers accepts the job, he gives response by pressing a button on a display unit installed in his taxi. Strategic Analytics estimates that by the year 2007, up to 55% of new cars produced in the U.S., Europe, and Japan will have built-in telematics function [SAN JOSE, Calif 2002]. A GIS/GPS based Intelligent Transport System was developed by the Bangalore Metropolitan Transport Corporation (BMTC) for monitoring the movement of their vehicles at an affordable cost [Kharola1 S.P et al]. This system was designed to convert the latitude and the longitude given by the GPS device into the nearest location and then the system will generate a log-sheet giving the location of the bus on the road network at certain periodic intervals in the form of location on a map. A sample output is shown below

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Satellite GPS

GPS unit installed on vehicles

Base Station

Figure 2.5: Global Positioning System for Vehicle tracking System [Padmanabhan .J, 2001]

Figure 2.6: Road map of GPS tracking [Kharola1 S.P et al] 2.4.2 Data collection and mapping The data collection and mapping are the important tasks done using GPS technology. GPS technology is spatially used in mapping of transportation network to complete the work quickly and reduces the cost. Each and every GPS data file contains data such as time trample, speed, longitude, latitude and satellite navigational data at regular time intervals. In Greece, Faculty of Civil Engineering of Aristotle University of Thessaloniki carried out a project named pilot project

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for mapping the road network with GPS [Tokmakidis & Tziavos 2000]. The mapping was carried out on National Highway road, which connects two cities Thessaloniki and Athens. The important method used in this road mapping is pseudo-kinematics. The result of this project shows that GPS/GIS are appropriate for both small scale and large scale road network mapping, and also cost effective. In June 1990, a special Differential GPS (DGPS) project was carried out [Byman & Koskelo 1991]. In this project a vehicle equipped with a GPS receiver and Dead Reckoning devices (DR) was used to collect numerical road location information and the attribute data while driving along the roads of Finland. The result of this project shows that the information obtained was 1-3 m of accuracy and at the vehicle speed of 60 km/hr. Faculty of Rural & Surveying Engineering of the Aristotle University of Thessaloniki for Hellenic Railway Organisation carried out a project [G. Mintsis et al 2000]. Aim of this project to develop a tool for mapping and monitoring the railway network 2.4.3 Incident management In today’s busy life everyone wants to live in urban areas due to which population as well as traffic congestions increased also resulted in increased accidents. GPS technology can be used for incident management and for monitoring the road networks. GPS technology is used in incident management (monitoring of the emergency vehicles and minimisation of their journey time in urban areas) has been proposed in the framework of research in Greece [Lakakis .K, 2000]. GPS technology is very much useful in determining the accurate position of an accident on the road network. GPS/GIS technology has the ability to produce accurate thematic maps with “black spots” (spots where a statistically significant number of road incidents occurred during certain time period) [Mintsis. G et al, 2004]. Intelligent Transportation System (ITS) provides three major elements of incident management system: Traffic Inspection (incident detection and verification), Clearance and Motorist Information. The GPS/GIS technology is implemented in the case of dangerous good transportation (e.g., fuels, chemicals etc.) where the positioning of vehicle provides useful information to the user (e.g., company, organisation) for the safe routing and scheduling of the fleet [Tzinieris .G & Delikaraoglou .D, 1992]. The GPS will be used in Indian railways for incident management system; because of rail accidents many people were losing their lives. Indian railway is the one network that connects the billion people living in the broad country. Nearly 13 million people travel by train every day. India’s vast rail network is set to get hi-tech solutions to prevent the recurring major crashes that blight its reputation [Monica .C 2003]. The main purpose of this hi-tech solution is • • • • If any problem by way of derailment or any other danger on the tracks will be picked up by the GPS and a warning will be conveyed via this device to the driver inside the engine cabin. Driver will be kept alert by a vigilance control device that will make sure they do not fall asleep while operating a train. If the driver performs no action for 20 seconds at a stretch, then the device gives out an audio-visual signal for the driver to move controls. If the driver fails to do anything, then the brakes come on automatically within the next 30 seconds.

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2.4.4 Vehicle navigation Vehicle navigation system was used to guide the drivers on roads to reach their destination where as vehicle location systems (VLS) are used for managing a fleet of vehicle. The vehicles of a fleet are fitted with GPS, which usually transmit the positional data of the vehicle to a central station. Public transportation have been improved by implementing a GPS-based vehicle location system, as in Paris (Ampelas & Daguerregaray, 1999) passengers are better informed about the intervals between buses and display information on Light Emitting Diode display and increasing the security of the service [Zarazaga-Soria et al,2000]. An over-the-head study of visual-manual destination entry using an originally equipment GPS-based navigation system was used in traffic on urban streets and motorways [Chiang .P, 2004]. In 1993, TravTek test [V. Inman et al 1996] was conducted in Orlando, Florida. The aim of this test is to provide in-vehicle navigation and dynamic route guidance system with real time traffic information

Route Planning

Route Guidance

Human Machine interface Wireless Communication Digital Map Database

Positoning

Map Matching

Figure 2.7: Basic modules (building blocks) for a location and navigation system [Yilin Zhao 1997] A digital map database contains digitised map information with a predefined format, which can be processed by a computer for map-related functions such as identifying and giving locations, road classifications, traffic regulations, and travel information. A positioning module focuses on different sensor outputs or a mobile device to identify the road travelled and each intersection approached. A typical stand-alone technique is dead reckoning, and a typical radio-signal based technique uses a GPS receivers. Map matching is a method of matching the position measured (or) received by a positioning module to a position associated with a location (or route) on a map provided by the map database module. Route Planning is the process of helping vehicle driver to plan a route prior to (or) during their journey, based on a given map provided by the map database module, if available, along with real-time traffic information received via a wireless communications network. Route guidance is the process of guiding the driver along the route 26

generated by the route planning module and it requires the help of an accurate positioning and map databases in order to determine current vehicle position and generate proper real-time guidance instructions, often turn by turn. A human-machine interface allows users to interact with the location and navigation computer and devices. A wireless communication module further improves the performance and increases the functionality of the system 2.4.5 Transport of hazardous Materials Global Positioning System satellites are used to locate position of a vehicle accurately. After September 11 2001, terrorist attacks on America. The project named Hazardous Material Safety and Security Technology Operation Test carried out by the Department of Transportation’s, Intelligent Transportation Systems Joint Program Office and the Federal Motor Carrier Safety Administration [Joseph P. DeLorenzo et al 2004]. In this project U.S. DOT was asked to find out the different areas in transportation that were susceptible of terrorist attack. In U.S.A ships transport daily 800,000 of hazardous materials, which may be explosive, toxic and other less flammable materials. The petroleum products are about 300,000 of the daily transported in U.S.A, which was transported by truck, ships etc. In this project GPS is used to locate load/cargo accurately and also provide a display unit, which is installed within a vehicle. Through this display unit drivers can have two-text communications system. The positions of a truck, ship etc are automatically transmitted to dispatcher center. The Chemical manufacturer BASF Corp. planned to start testing a GPS system with real-time computer interface on 200 of its tank cars [Marybeth Luczak 2004]. These tank cars carry poisons products. This GPS system provides security and fleet efficiency to tank car drivers. Lat-Lon Inc. and Star Track LLC offer tracking and tracing devices for tank cars, which in known as Lat-Lon’s RailRider. In this system GPS is combined with the chlorine detection sensor. The different information about tank cars is transmitted from GPS to appropriate authority. Then the GIS operator uses this information to locate address on a city digital map. If any emergency occurs the GIS operator tries to find out the schools, colleges nearest to that location for evacuating area. During this data transmission data is encrypted for security purpose. 2.4.6 Limitations of GPS After May 2000 Selective Availability (SA) has been removed, this was the main cause for errors during positioning. There are some problems with GPS based AVL such as in urban areas, there are big building that abstract the satellite signals. The GPS device receives poor quality of signals. Adding additional sensors with GPS devices can solve this problem. A GPS receiver takes several minutes to start (cold start) to achieve the MS location fix. In emergency services, it is considered to be major delay for many applications. Also the question of size, cost and power consumption are main cause of limitation

2.5 Global System for Mobile Communication (GSM)
In present commercial society cellular communication system has become a new trend for many different applications. GSM (Global System for Mobile Communications) is developed by European Telecommunications Standard Institute (ETSI). GSM (Global System for mobile telecommunication) comprises the CEFT-defined standardization of the services,

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functional/subsystem interfaces, and protocol architecture based on the use of worldwide standards produced by CCITT and CCIR for a pan European digital land mobile system primarily intended to serve users in motor vehicles [Rahnema Moe 1993]. GSM provides powerful messaging service that enhances and facilitate roaming through automatic network location detection and registration. Most popular technology for real-time communication in transport industry is ‘telegeomonitoring’. Telegeomonitoring system is a combination of geographical information system and telecommunication. Telegeomonitoring system is used for monitoring the transportation of hazardous materials [Boulmakoul Azedine 2005]. In the field of transportation, for environmental monitoring (e.g., population monitoring, Hazmat monitoring) main focus is on GIS. For environmental monitoring use of telecommunications and positioning system is highly important. Telegeomonitoring is also widely used in dynamic guidance and fleet management of vehicles as shown in below figure 2.8.

Figure 2.8: Hazmat telegeomonitoring [Boulmakoul Azedine 2005] The integration of GIS, GPS, and GSM technologies are applied in different fields such as logistic management, intelligent transportation, defence security, electric power distribution and urban planning etc to provide location based information on digital map. A Web GIS-based GPS Vehicle Monitoring System [Qimin et al, 2003] with three-tier architecture has been developed to monitor real-time location information of certain moving vehicles on electrical map online. In this system GSM is used as a communication platform in GPS-based vehicle monitoring systems because of its high frequency, capability, reliability, wide coverage, open interface and so on. How Web-based GPS vehicle monitoring is developed based on GSM is shown in below figure 2.9.

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Figure 2.9: GSM/GPS/GIS based System Architecture [Qimin et al, 2003] Another example of GIS/GPS/GSM is Modular Mobile Dispatching System (MMDS), which consist of a GIS database, a GPS receiver, a GSM as communication module and other I/O devices for dispatching of vehicles. A vehicle driver in emergency uses MMDS [Hsiung et al 2003] and get help within 4 minutes from the time a call made from the vehicles to the call center through GSM communication, then the call centre operator plot the driver’s location on a map using GIS, locating and dispatching the ambulance towards the location by informing the target help through GSM, and route navigation is provided using GIS database. This example is shown in below figure 2.10.

Figure 2.10: Modular Mobile Dispatching System (MMDS) [Hsiung et al 2003] An AMBULANCE project (R & D project) was developed in corporation with European Commission within the framework of the Health telematics program [Pavlopoulos et al 1998]. 29

This system uses the GSM to have over 95% of the coverage. This system consists of two modules such as. • • The mobile unit(ambulance site) The consultation unit(hospital site)

The working of mobile and consultation unit are shown in figure 2.11.

Figure 2.11: AMBULANCE system architecture [Pavlopoulos et al 1998]

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Chapter 3

Methodology
3.1 Ambulance Management System prototype using GIS/GPS/GSM
The proposed Ambulance Management System (AMS) follows a step by step process. If an accident occurs on the road network, information will be sent to nearest traffic control room which is then forwarded to nearest emergency hospital, fire station and police station [Kowtanapanich et al 2003] from telephone booth or mobile phone.

Figure 3.1: Information flow after accident occurred on road network

When a call comes from accident site to traffic control room, the controller informs this information to nearest emergency hospital, police station and fire station (if any fire occurs on the spot). Emergency hospitals will use Ambulance management system (AMS) to find the accident site on the road network (nearest road segment and landmark) and find nearest ambulance to accident site and allocate that ambulance to accident site. AMS tools are used to find the fastest path from nearest ambulance location to accident site; from accident site to nearest hospital; route map and directions are sent to ambulance driver. Also some other information is also provided to ambulance driver such as. • • Fastest path from nearest ambulance location to accident site & from accident site to nearest Hospital If accident occurs during peak hours different alternative fastest paths are provided other than the normal fastest paths on major roads but this time ambulance driver should follow 31



fastest path on both major & minor roads to avoid congestion and time delay to save the life. If once ambulance is struck in congestion it takes more time to reach the accident area

The main aim is to help the ambulance in reaching the accident area as fast as possible without getting delay due to the congestion on road network.

Figure 3.2: Methodology for AMS using GIS

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3.1.1 Data Collection Ambulance management system (AMS) data is collected from three sources of map data, realtime data and police/transport authorities Map data: Map data is collected from GIS professionals of Hyderabad city. Map data consist of major roads, minor roads, hospitals, fire stations, landmarks and police stations. Spatial data: In AMS real-time location of an ambulance can be tracked using GPS/GSM (Global Positioning System). Police/Transport Authority reports: When an incident occurs on road network information about incident is recorded by police authority in the form of reports. Transport authority’s record the information about the major/minor road networks 3.1.2 GIS database GIS database is developed combing these three map, spatial and police/ transport data. Theme Road network Fields Name One-way Speed limits Length Drive time Category Name Label Category Name One-way Speed limits Length Drive time Category ID Employees Description Name of the road Contain information of one-way road Speed limits on that road segment Length of the road Drive time calculated based on speed limit and length Category key number Name of the hospital Label of the hospital Category key number for private and govt hospitals Name of the road Contain information of one-way road Speed limits on that road segment Length of the road Drive time calculated based on speed limit and length Category key number Identity number Responsible employees for telemedicine , including driver(locating using GPS)

Hospitals

Minor road

Ambulance

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Theme Accident

Police Station

Fields Amb_ID Nearest_La A_cause Date Time Hospital_T ID Name Label ID Name Label

Description Identity number Nearest landmark Accident cause Accident date Accident time Hospital where patient is moved Identity number Name of the police station Label of the police station Identity number Name of the police station Label of the police station Table 3.2: AMS database

Fire station

Figure 3.3: GIS database for analysis in ArcMap9.1 34

Map Data: • Major roads are connected together to form road network of Hyderabad city. This road network is used by vehicles for transport where the traffic flow is steady and cause for traffic congestion. These major roads are represented as chain of lines in Ambulance Management System (AMS) user interface. Minor road networks are small streets in-between buildings. These are used for walking, cycling and even ambulance can use if there is a congestion on major roads. Minor road is represented as line feature in Ambulance Management System (AMS) user interface. Emergency hospitals in the city are responsible for allocating ambulances to accident area and take it back for providing medical care. Emergency Hospital is represented as point feature in Ambulance management system (AMS) user interface. Police & fire stations in the city are responsible for recording incidents on the road networks and providing the safety to public. Police & fire station is represented as point feature in Ambulance Management System (AMS) user interface.

• • •

Spatial Data: In AMS real-time location of an ambulance will be tracked using GPS (Global Positioning System).GPS technology is spatially used in mapping of transportation network to complete the work quickly and reduces the cost. A GPS device will be installed on each and every ambulance, and signals of this GPS will be sent to control room (Emergency hospital). The data collected from GPS will be stored in database as x, y co-ordinates of the ambulance location on the earth surface. The location of the ambulance is represented as point (x, y co-ordinates) feature on the road map. Police/ Transport Authority reports: When an incident occurs on road network, following information about incident will be recorded by police authority such as. • • • • Patient details. Incident type. Location information. Hospital to which patient has been transported.

Using these records we can find out where and on which road network accidents occur frequently and cause of the accident. Transport authorities record the information about the major/minor road networks such as, • • • • • Demographic data Road network Speed limits Length of road segments Junctions 35

3.1.2.1 Database Design and Analysis Below figure shows how data is stored in a database and accessed by the emergency service providers. Database regarding the roads, incidents and facilities are available at police stations, hospitals and fire stations. In our AMS user interface database is collected from these emergency service providers (police, fire and hospitals) and from the real-time (GPS/GSM) movement of ambulances on the road network. When there is a call for service (ambulance) GIS operator at dispatch centre uses AMS user interface to inform the ambulance regarding the work it has to perform. This same prototype can be used by the police and fire authorities to perform the following functionalities. • • Find fastest route from nearest police vehicle to crime area and finding the crime occurred area on the city digital map and also back to nearest police station Find the fire spot on digital map and allocating the fire vehicles on fastest route to reach the fire spot.

Call for service

Fire Station Database

108 Operator

Dispatch Center E-Hospital ArcGIS system with Street Network Network Analyst Database

Database

Police Station Database

AMS

GPS/GSM

Figure 3.3: Database use in AMS

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3.1.3 Analysis (GIS/GPS/GSM) The effective management of ambulance in order to achieve immediate transportation of patients from incident site to the nearest & appropriate emergency hospital plays a vital role in health services offered to citizens. An effective routing and districting of ambulances will minimize their response time and thus improve the way emergency incidents are being handled [Derekenaris .G 2000]. AMS architecture is an integration of ArcGIS9.1, GPS and GSM technologies. In Each ambulance a GPS receiver is installed to determine its real-time position (x, y co-ordinates) based on the signal transmitted by satellite and information will be forwarded to emergency hospital via GSM modem, this can be achieved by GSM network. Through GSM network useful data such as route map, directs and voice messages can be transmitted. Each ambulance is also equipped with a computer or a mobile data terminal (PDA) to display the route computed by the AMS (Ambulance Management System) operating in the emergency hospital.

Figure 3.5: GIS/GPS/GSM technology Emergency hospital (base station) will exchange data with the ambulance through the GSM network [Derekenaris .G 2000]. In the emergency hospital (base station) there will be a computer dedicated to communicate with the ambulance and other one for the operation of the AMS user interface. The primary functions performed by the GIS (AMS) operating in emergency hospital are as follows [Derekenaris .G 2000]. • • • Finding the site of the incident & ambulance location Depiction of accident & ambulance on city road map Choosing the nearest ambulance to handle an emergency incident 37

• •

Routing an ambulance to the incident site and from there to the closest emergency hospital. If accident occurs during peak hours ambulance will be directed to fallow the minor & major road fastest path other than regular fastest path on major roads

One of the most important responsibilities of public safety is efficient and effective emergency transport and care system. Middle East Technical University (METU) Emergency services, Ankara Turkey build an immediate, rapid and efficient medical transport system prototype called AML [Gülden et al 2004]. Emergency Hospitals are important as police and fire stations. Emergency hospitals provide immediate care for victims of sudden and serious injuries. When an incident occur patient transportation to Emergency hospital seems quite simple. Ambulance Management System (AMS) preferably combines technology, strategic planning and clinical proficiency to ensure an immediate efficient response to each and every call for help [Altıntaş & Nakil 1997]. In AMS time plays most important role to save human lives. In AMS for routing, ambulance location is the starting point and nearest hospital is the final destination respectively. The accident site address, ambulance location, major & minor roads and hospital location information is co-ordinated to obtain results using the AMS.

. Figure 3.6: AMS architecture

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3.1.4 AMS information for decision making AMS performs chain of events which leads to the intervention of an ambulance to the scene of an accident. The following four steps are performed by AMS. (1) Incident location finding (2) Call screening (3) Ambulance dispatching (4) During peak hours, routing of Ambulance Emergency Number When you witness an accident at Charminar road and victim is bleeding first you want to help him and save his life. The first question arises ‘what do you do?’ first you want to call the emergency number. Although there are various numbers for different emergency services, but the number 108 is a centralised one. Let the emergency may be of any kind police, fire and medical just dial 108. In Hyderabad city emergency service providing company EMRI developed sensereach-care paradigm for emergency management [Changavalli Venkat, 2005] on August 15, 2005. The call centre of 108 at Byrraju foundation on Medchal road receives on an average 2,200 calls per day from twin cities. 3.1.4.1 Incident location finding Most important details about the accident should be confirmed i.e., location and type of crash. Location is noted relative to street intersections in urban areas and crash refers to head-on, angle, sideswipe, rear end or other common collisions [Chuck Reider 2006]. One who witnessed the accidents tells the suitable landmarks to identify the accident location such as identifiable buildings road turns, road junctions, street name, colony name, etc. These landmarks are used to identify the accident spot along each road. 3.1.4.2 Call screening When informer informs accident site information, Ambulance Management System (AMS) operator will make the address query to find the accident location on the city map. In case if operator didn’t find accident site on city map than AMS operator will call back the informer for confirming accident site location. If the AMS operator finds the incident site, then he will locate the ambulance location on the city map using the GPS/GSM.

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When call is received

Finding the ambulance

Does accident site visible using GIS?

Call back to informer

Figure 3.7: If accident site didn’t find than

Some examples of call screening methods such as HNIT Limited., one of the leading GIS consulting in Iceland, joined hands for the development of an emergency response computing system, which includes computer telephony, RDMS, GIS and different protocols for SMS and pagers. When anyone needs emergency service just need to dial 112 in Iceland, then the telephone operators dispatch service from more than 200 different response agencies (fire, police, and ambulance) across country (GIS for Telecommunication Professionals in Europe 2000). Each agency also has its emergency number for service. GIS system is used to find the places like municipalities, streets, postal codes to provide quick service for that area. A telephone switch electronically identifies the caller’s automatic identification number and that number is matched in the Oracle database. The database provides the operator with the caller’s address and postal code information is then georeferenced to locate the incident and to determine the appropriate agency to respond. In moments the operator has all the necessary information to dispatch a police, fire, medical, or ambulance unit [GIS for Telecommunication Professionals in Europe 2000]. In Europe emergency service is also available where the nearest emergency service provider is notified by dialling three digits 112 (911 in USA) 3.1.4.3 Ambulance dispatching Ambulance Management System (AMS) integrates common database operations such as query and statistical analysis with the unique visualization and geographic analysis benefits offered by maps [Franklin .C, & 1992, Keenan P. 1998]. AMS has capability to analyze spatial networks; it is a decision making tool for districting and routing of vehicles. Ambulance management system (AMS) prototype is the motivated from [Derekenaris .G 2000, Tsai et al. 2002].The AMS prototype architecture is an integration of GIS, GPS and GSM technologies but the way it deals with the ambulance routing problem is completely different. In AMS more routing solution network analysis tools are used to solve the targeted problem. In each ambulance a GPS receiver is installed to determine its exact position based on the signal transmitted by satellite and a GSM modem in order to transmit its position to a base station, this can be achieved by GSM network. The primary functions performed by the AMS [Derekenaris .G 2000].

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• • • • •

Tracing the ambulance positions and hospital location on the city map Finding the accident site using the road and nearest landmark information Allocating the nearest ambulance on the fastest route Fastest routing of a nearest ambulance to the incident site and from there to the closest emergency hospital. Incidents data is stored for generation of statistics regarding incidents

Ambulance Management System(AMS) considers these facts and provides fastest routes for the ambulance (considering congestions) TRAUMA CARE CONSORTIUM (TCC) is a unique non profit public charitable service and the first of its kind in India which provides fully equipped ambulances for emergency movement towards road accident victims to hospitals (Chennai city) [Thirumalaivasan.D & Prof. Guruswamy .V]. TCC used GIS for finding optimal route of their ambulances based on shortest travel time. This study concluded that during the emergency situation finding the shortest route need not be the best route because shortest time is preferred over shortest distance. Shortest time preferred also when the road width is narrow or more number of signals & turns exist, or higher volume of traffic and so on. National Center of Immediate Assistance (EKAB) has [Derekenaris.G 2000] designed GIS subsystem for the ambulance management. The same type of system like [Derekenaris et al 2000] was proposed by [Tsai et al. 2002] for Atlanta Police Department in Georgia in order to reduce emergency response time. The research idea of this system to decrease response time is • • • Reliable location of vehicles, incidents, hospitals and fire stations. Integration and collaboration of related agencies. Fast and related distance and route calculation.

Tsai et al. (2002) includes GIS/GSM/GPS and using Microsoft’s Access and Visual Basic 6.0 ESRI’s MapObjects and NetEngine as back-end and front-end tools for the interface. When an emergency call is received this system locates the incident site, finding the moving vehicles, calculating shortest distance from vehicle site –incident site. Tsai found that this system is helpful in reducing response time for police dispatching and tracking system There are some other research works from where AMS got motivated, in China QTIMP project was designed, which is mainly based on G3 technique integration. This G3 technique integration was used to provide safe transportation and maintenance of Qinghai-Tibet Railway [Wang 2004]. G3 was a combination of three technologies such as geographical information system (GIS), global positioning system (GPS) and global system for mobile communication (GSM). G3 is used to provide an extremely accurate location tracking system. The telematic system of automobile is the TCU (Telematics Communications Unit) which is placed on the vehicle is online connected with one of the central service station through radio waves [Bãdut Mircea 2004]. This telematic system provides services such as ambulance dispatching in incident situations, real-time navigation, and traffic information and providing technical support for troubled onboard cars.

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Figure 3.8: Telematics Applications [Bãdut Mircea 2004] [Lin et al 2003] proposed G3 system to track low flying aircrafts and vehicles on a digital map in real-time. This G3 system was a combination of GPS, GIS, and GPRS (which is based on GSM technology). 3.1.4.4 During peak hours, routing of Ambulance Most of the Indian cities are facing crucial traffic congestion. Growing traffic and limited road space have reduced peak-hour speeds to 5-10 kms per hour in the central areas of many major cities [Singh K. Sanjay 2005]. According to Centre for Science and Environment (CSE) there is major reduction in motor vehicle speeds. Traffic congestion occurs during peak hours in Indian cities increases time delay, accidents problem and pollution level. According to the Ministry of Road Transport & Highway in 2001 about 80000 people were killed in road accidents and 5 percent annually increase in road accidents [Singh K. Sanjay 2005]. In road safety research rapid response and treatment of road accident victims is of major concern. From the road safety studies it is recognised that time is a crucial factor in dealing with emergencies resulting from road traffic accidents [Moore David], it is based on concept of Golden Hour. Time during victims may face death such as. • Immediate death occurs within seconds after accident. • Late death occur within days or weeks of the accident AMS is based on the concept of Golden hour, during the peak hour most of the time roads are congested. AMS consider the congested roads and calculate the fastest route using both major and minor roads. In the normal situation fastest route is calculated on minor roads. The critical time elements in emergency are listed in the following [David Moore].

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Figure 3.9: Critical Time/ Space Elements [Moore David] Apollo hospital has launched its two-wheeler ambulances aimed at reaching accidents victims in the golden time (first one hour) or the platinum time (first 10 minutes), which is the most crucial time that makes the decision of their life or death. This is the only two-wheeler ambulance [Apollo Hospitals Enterprise Limited]. These two-wheeler ambulances can travel easily through congested roads to reach accident sites and play a key role in reducing the number of victims who die at the accident site because of delay in arrival of ambulances and congested Indian roads. These two-wheeler ambulances come with in-built splints to immobilize broken bones and stabilize the cervical spine (the area most susceptible part to injury in a road accident) [Apollo Hospitals Enterprise Limited]. Apollo hospital can use our Ambulance management system for faster routing of two-wheeler when roads are congested during peak hours. Because our AMS is designed to find the fastest route both on major & minor roads, which is more useful for two-wheeler ambulance of Apollo hospital.

3.2 AMS User interface Development
3.2.1 Mechanism GIS based Ambulance Management System was developed for routing of ambulances during accident on road. In this system the main issues were the fastest path, nearest ambulance, hospitals, identifying the accident location and storing the accident information in the database. Mechanism involved in the development of AMS is described below.

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3.2.2 Fastest Path Using the AMS, GIS operator at the hospital can create the route, which is quickest, shortest or scenic depending on the constraints. Because the travelling of ambulance to reach the incident in short duration is important and not the distance, so the constraint is time when the route is the quickest route. Any speed limit or driving time attribute serves as the impedance when determining the best route. Increase in attributes plays no role when computing the solution. For example , if you choose time as impedance attribute and also want to accumulate distance also an impedance attribute, but only time attribute is used to optimize the solution The route analysis layer consists of different components such as. • • • Stop feature layer(ambulance, accident, hospital) Barrier feature layer(congested areas where ambulance can’t travel) Route feature layer(generated route from ambulance-accident-hospital)

3.2.3 Nearest closest facility Using the AMS UI, we can find the closest facilities such as hospitals & ambulances and the directions of travel towards or away from the city. After finding the best route to or from ambulance to accident and accident to hospital, it will display directions to travel in direction window. Using AMS, when finding facilities (ambulance, hospital), we can give the cut-off value beyond which AMS should not search for a facility (ambulance, hospital). For example, any hospital that takes not longer than 15 minutes to reach from incident spot will not be included in the results. AMS UI allows you to perform multiple closest analyses simultaneously, that means we can have multiple incidents and find the closest facilities (hospitals, ambulances) to each incident. The Closest facility analysis layer consist of different components such as • • • • Facilities feature layer(ambulances or hospitals) Incidents feature(accident spots) Barrier feature layer(congested areas where ambulance can’t travel) Route feature layer(generated route from ambulance-accident-hospital

3.2.4 Rapid prototyping model for AMS The desire not to ‘waste’ of software developers laid to rapid prototyping. The management of the company decides before the rapid prototype is built that portions may be utilized in the final GIS interface, provided that thus portions pass the same quality assurance test as the other software components. AMS rapid prototype model is a working model that is functionally

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equivalent of a product. The rapid prototyping model of AMS is target to let the clients (Hospital authorities) to interact with the system and experiment with it. Many of the software developers use the rapid prototyping model because the rapid prototyping model has been validated by the client (GIS user) himself. In the AMS prototyping system preliminary working model has been created that lessen the need to repair the design during or after the implementation of the system. The main thing is that AMS prototype builds rapidly and, modified rapidly to reflect the GIS user’s needed. Thus, speed is the essence of AMS prototype development.

Rapid prototype Verify Changed Requirements Verify Refine prototype Test

Opertaion mode

Retirement Development Maintenance

Figure 3.10: Rapid prototyping model of AMS [Schach &Stephen .R 1997] In rapid prototyping model most of the time, the developer reuse the modules of the previously successful system. Using the coding and design of previous system, we can save the design and coding time. In our Ambulance Management System (AMS), we used the modules from the ArcGIS 9.1, to create our model. Once the AMS prototype is created and tested, then it is forwarded to operation mode. In operation mode client experiment with the prototype and if the client is not satisfied than again developer tries to design & code. After refining & testing the prototype, again client is asked to use it. This rapid prototyping process continues until the client is satisfied. 3.2.5 Software development for AMS of Hyderabad City In the development of Ambulance Management System (AMS) following software is used. • ArcGIS version 9.1 • ArcGIS extension Network Analyst • Visual Basic 6.0 programming language

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3.2.5.1 ArcMap 9.1 In ArcGIS Desktop, ArcMap is the central application for all map-based tasks. ArcMap application is used to perform the following task with geographical data. • To perform analysis • Explore and edit • Create maps, graphs and reports, etc The ArcMap working model consists of the map display area, table of contents, number of toolbars and menus for working with map and its attribute data. There are two ways to view map data in ArcMap. Geographic data view: Where geographical data is analyzed, symbolized and compiled. Layout View: Where Geographic data view, data frames are composed onto pages for printing and publishing. 3.2.5.2 ArcGIS extension Network Analyst ArcGIS Network Analyst is a powerful extension for routing purpose, and used for making network-based spatial analysis such as • • • • • • • • Point-to-point routing Drive-time Analysis Route directions Shortest path Optimum route Origin destination Closest facility Service area definition

3.2.5.3 Visual Basic Programming language Visual basic programming language is an Object-oriented & Event-driven programming language. Visual basic provides rapid application development (RAD) environment for windowsbased graphical user interface (GUI). In Visual basic programming every event is a method and controls placed on form are classes. Using Visual basic we can customize ArcGIS9.1 to create entire custom applications for different GIS analysis. In Visual basic customization of ArcGIS9.1 .dll files are used as ActiveX controls. 3.2.6 AMS user interface flow Chart The flow of information using the AMS interface in finding the accident location, and fastest route from nearest ambulance to accident , and fastest route from accident to nearest Hospital. The condition applies when the accident occurs during peak hours such as fastest routing on both the major and minor roads. 46

Figure 3.11 AMS flow chart

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3.2.7 AMS Input Sources 1. Network dataset 2. Roads with one-way 3. Driving speed limit on roads 4. Names of all available roads 5. Emergency Hospitals 6. Real-time Ambulance position 7. Accident on road 8. Topographical map at scale 1:25000 numbered 56-K/ 7 / NE 9. Topographical map at scale 1:25000 numbered 56-K/ 7 / SE 10. Topographical map at scale 1:25000 numbered 56-K/ 7 / NW 11. Topographical map at scale 1:25000 numbered 56-K/ 7 / SW 3.2.8 Themes for Analysis The different spatial features of Hyderabad city in the form of different themes are added to the project according to there use. Themes which are used for Ambulance management System (AMS) are added to the current project. The available themes are as follows. • • • • • • • Road Network with system generated junctions Emergency hospitals Ambulances (real-time technology) Lakes Rivers Minor Road Network Study Area

Theme’s attribute table is updated using necessary information to be analyzed in the AMS. The fields (columns) are added to the theme attribute table and entering the required information for spatial analysis, in their records (rows). 3.2.9 Designed Interface of AMS 3.2.9.1 Menus To make the Ambulance Management System (AMS) more user-friendly, navigation should be considered as the most important aspect of the GUI. So menu-bars are added to UI. Menu bar contains different menus (with common commands) to perform different functionalities on spatial data. AMS interface menus and their functionalities are described in the table 3.2.

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Menu Name File

Sub Menu New Open Save Save As Add Theme Print Preview Print Map Properties Exit Redo Undo Copy Cut Paste Delete Find Data View Layout View Zoom Layout Toolbars

Function Create new Open the existing data Save the analysis Save the analysis with any other name To add new themes Print layout of the data Printing the data Open the properties of selected feature To exit To redo the analysis To undo the analysis Copy the selected data Cut the selected data Paste the data which is copied or cut Delete the data Find a select feature View for browsing the geographic data on your map view for exploring, displaying, and querying the data on your map To zoom in or out on Layout view ESRI ArcMap & user defined toolbars Selection using an attribute query Selection using an location query Selection using an graphical feature query Statistical analysis on attribute data To clear selection of the selected feature Setting up the GPS connection Displaying the GPS position window Closing the GPS display properties Pan on the current position Closing the log setup of GPS Setting the display properties To see layer overview see a magnified view of a small area To see contents of layers To create graph from the current layer To create report from the current layer To open ArcCatolog To open ArcToolBox

Edit

View

Selection

Select by attribute Select by Location Select by Graphics Statistics Clear Selected Feature GPS connection Setup GPS position Window Clear Display properties Auto Pan Log Setup Display properties Overview Magnifier Table of Contents Graphs Reports ArcCatolog ArcToolBox

GPS

Tools

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Menu Name Network Analyst

Sub Menu Emergency Locations New Route New Facility New Service Area New OD Cost Matrix Options

Function To find emergency locations & facilities To find the fastest route To find the nearest facility To find the new service areas To find route between Origin & destination Other options Table 3.2: AMS Menus

3.2.9.2 Toolbar The toolbar consist of number of buttons with icons, clicking on one of these buttons executes a command or function. Toolbar is graphically related to menu bar. Buttons on toolbar are used to perform frequently accessed functions. AMS toolbar’s buttons and their functionalities are described in below table. Tool Name Zoom in Zoom Out Fixed Zoom in Fixed Zoom out Pan Full extent Go back to previous extent Go to next extent Select feature Select elements Identity Measure Zoom to GPS position Pan to GPS position Hide/Show network analysis window Create Network location Select/Move Network location Solve Direction window Network identify Build network dataset Open GPS connection Functionality Zoom in by clicking a point or dragging a box Zoom out by clicking a point or dragging a box Zoom in center of your map Zoom out center of your map Pans the map Zoom to full extent of the map Go back to previous extent Go to next extent Select the feature by clicking or dragging a box Select elements by clicking Identifying the feature by clicking Measure distance on map Zoom to current GPS position Pan to current GPS position Hide/Show network analysis window To create Network location on Map To Select/Move Network location on Map To solve network , to form routing Window with directions of route To identify a network location on road network To build the network dataset Open GPS connection for update from GPS

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Tool Name Close GPS connection New fastest route New closest facility New Service Area New OD cost matrix Emergency Locations Find accident Send Route direction Rotate Refresh view

Functionality To close the current GPS connection Find the fastest route between locations Find the nearest facility for accident & route Find the service area Find the route between Origin & destination using cost attribute Loading the emergency & facility sites Finding the Incident site Sending the route & turn window to the driver Rotate the Map Refresh the view to have current view Table 3.3 AMS Tools

3.2.9.3 Applications of AMS

Figure 3.12 AMS Interface model 51

3.2.10 Database Design of AMS user interface The Object-oriented design model is good for GIS database but relational database management system also contains good features. The combination of Object-relational database model makes things easier to GIS database model [Shekar & Chawla 2003]. Ambulance Management System (AMS) describes design and implementation of geographic data in an Object/relational database. This user interface was developed using VB.net programming language. AMS user interface was developed to show the geographic data and their analysis (finding incident, facilities and fastest routes). The data stored in the database was accessed by GIS operator at Hospital, who runs AMS user interface. The ArcGIS uses relational database engine to manage text or numeric data in a multithreaded environment with a great deal of stability and good performance and supports object-oriented keywords. The objects were made persistent by using the Object-relational database management system. Data in database was modelled by points, lines, polylines and polygons. The aim of our experiment is to show how geographic data is represented, that is used in a geographic database of our AMS.
Presentation Layers, Fastest Routes, and facilities Operation Fastest Route analysis

Operation Manager Geographical Objects Buildings, Water bodies Roads OMT Fuctionality Menus, Toolbars

Lines Polygons Junctions, Hospitals, Ambulance, Accident

Table Layers, Network L

Classes (AT) GIS Database Point, Line, PolyLine Polygon

Points Modeling Manager

Database manager

Figure 3.13 OOGIS architecture of AMS user interface

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Object: Object is an instance of a class and a self-describing data structure, which is safe and protected. The Object can be private, public, protected. A real world object is also referred as entity. The objects interact with each other through messages. In object-oriented system objects are independent of each other and a change in one object cannot affect another object. Classes: The class describes the objects (data structures), methods (algorithm) and message protocols (external interfaces). The class provides the encapsulation mechanism to encapsulate attributes and methods into a single unit, this provide safe software components and high level of modularity. Data collected from transport authorities of Hyderabad city. The AMS prototype was tested using VB.net Object-oriented language program and Object-relational DBMS on Windows XP. The VB.net application contains the following modules. • • • • The operational manager The database server The interface Manager The modelling manager

The data types created in the database are similar to the classes implemented in VB.net or Java. The types, the classes and the tables have a similar description. The data types created in the database are same that the data types described by the OMT design. With this AMS prototype interoperability and the data exchange can be improved by this representation of OOGIS.

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Chapter 4

Usability Test (Evaluation)
A team of five GIS users was formed; these GIS users have good knowledge of analysing the data and getting results. They were asked to use the Ambulance Management System user Interface (AMS). The AMS evaluation test was conducted at Linköpings University on Thursday 11th of May 2006 at 4:00 PM. Before starting the testing, AMS is briefly described and it’s uses in emergency situations. During the testing each and every GIS user is constantly observed and how well they were operating the system. The testing of AMS continued till 5:00 pm. After testing the user interface, questionnaires were distributed for feedback. From the GIS users feedback it was found that • • • • • • • They were satisfied with the present user interface Minor changes needed to be done regarding design This UI will need some changes , when it is implemented in the real-world Funding will be the difficult task for the whole, considering the study area. As a whole, methodology is quite good Lessen the time to reach the accident site to hospital Model is a really solution for peak hours.

4.1 User Test
GIS user is asked to use the Ambulance management system (AMS) user interface to perform the following task. • • • • • Finding the Accident Location Finding the ambulance locations in real-time (using GPS) To solve the fastest route from nearest Ambulance to accident site(during normal and congested roads) To solve the fastest route from accident to nearest Hospital (during normal and congested roads) Also asked to handle more than one accident situation

4.2 Followed Paradigm
4.2.1 Observations How well GIS users uses the Ambulance Management System (AMS) user interface to perform the following needs were observed.

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• • • • •

Using menus of AMS user was able to select functionalities in solving ambulance routing problems Using the tools on toolbar AMS was user able to select frequently used functionalities just by click on it. User felt comfortable with advanced networking tools on toolbar for solving routing problems After solving routing problem user able see a magnified view of a small area more clearly Results obtained finally by clicking route solve function than send forward by clicking send route direction button on toolbar

The observations made during the testing were noted down to make changes in the UI. 5.2.2 Interviews During the testing each GIS user is interviewed regarding the AMS UI performance. After completion of the testing all the GIS users were interviewed together regarding the usage and design. • • • • How is the design? Whether the Interface is performing all the functions which it is meant to perform? Is there any error during the Testing? Any future advances required?

5.2.3 Questionnaires Questionnaires were distributed to GIS users after completing the test; questionnaires consist of ten questions, primarily regarding the usage and performance of the AMS UI.
User Feedback for AMS

4

3

Performace 4 Interactivity GIS Role GPS/GSM 5 Output Future Usage

3 3

Figure 4.1: Result from Evaluation

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The figure 4.1 shows the feedback from the GIS-users. The feedback was taken in terms of six parameters i.e. performance, interactivity, GIS role, GPS/GSM, Output and Future Usage. The graph describes that most of the GIS-users had positive response for Ambulance Management System (AMS) user interface. Three users appreciated the performance of the application, while the interactive interface design appealed to 4 users; 3 users supported and appreciated the use of GIS, GPS and GSM technologies used in the model. All of the users were satisfied by the results obtained by the system. 4 users gave a positive reply on implementing the model in future for a real time scenario. There were some suggestions to eliminate few errors identified by the users and improve the interface.

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Chapter 5

Results
Creating a network dataset in ArcGIS 9.1 Network analyst tool enables us to perform network analysis. Network dataset is a type of network data which is specially needed for network analysis. Using the AMS UI Create Network dataset tool we create network dataset using road Network shape file (polyline). The network dataset which has been created consist of three layers • Road segments as polyline feature (edges) • Junctions as point feature(system generated junctions) • Road Network itself 1) After creation of network dataset following spatial features are added to the ArcMap. • Network dataset (junctions, edges) • Accident location (which is known from a informer located using the nearest landmark) • Ambulance location is located on the road network using the GPS (ArcGIS9.1 extension Tracking Analyst) • All emergency hospital which are available are added

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1) Using the AMS UI to identify the accident on the road network.

Figure 5.1: To identify the accident

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2) Using the AMS UI to identify the ambulance locations on the road network in realtime using GPS/GSM coordinates.

Figure 5.2: To identify the ambulance locations

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3) Using the AMS UI (Route analysis), we have analysed the fastest routes through which all the ambulances can reach the accident occurred site.

Figure 5.3: To identify fastest route from all ambulances to accident site

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4) Using the AMS UI (Closest facility analysis), we have found the ambulance which can fastly reach the accident site as compared other ambulances is analysed.

Figure 5.4: To identify fastest routing ambulance to the accident

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5) Using the AMS UI (closest facility analysis), we have found all hospital (facilities) and analysed the fastest route from the accident occurred site to hospital.

Figure 5.5: To identify fastest route to the hospital

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6) Where more than one accident occurrs on the road network, using the AMS UI (closest facility analysis), we have analysed the fastest routes through which ambulances can travel to reach all the accidents

Figure 5.6: Multiple accidents Scenario I

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7) Using the AMS UI (closest facility analysis), we have analysed the fastest routes from all the accidents; travel to reach the hospital immediately.

Figure 5.7:

Multiple accidents Scenario II

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8) During the peak hours since the routes are congested, ambulances are allowed travel through both the major and minor roads.

Figure 5.8: During peak hours situation I

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Figure 5.9: During peak hours situation II

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Figure 5.10: During peak hours situation III

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Figure 5.11: During peak hours situation IV

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Figure 5.12: During peak hours situation V

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Chapter 6

Discussion
6.1 Conclusion
Indian population and thereby the vehicles are increasing at the same time causing congestion on road networks. AMS is designed by analyzing the ground situation of Hyderabad city, for example the problems faced by the inhabitants while travelling on the road network. Especially the problems faced by the emergency service providers like hospitals during transport of a patient. Ambulance management system (AMS) plays a significant role in solving routing problem of an ambulance on the Hyderabad road network when need arises to transport a patient to the nearest hospital. Our AMS significantly solve ambulance problem like fastest routing of an ambulance using GPS/GSM. AMS also analyzes roads interrupted by the congestion and other activities during peak hours and calculates the fastest route. AMS is capable of handling multiaccident situation. It is found how well the interagation of GPS/GSM will be used to find the real-time position of an ambulance on Hyderabad road network. This position information will be spatially analysed using GIS. Andhra Pradesh state government policy towards adopting positioning technologies is at the beginning stage but soon it will adopt fully. Now a days GSM is used by everyone in India for mobile communication system and used to show the current area location of a user on the display screen. At the same time GPS needs some more time to get established in the Indian market. For implementation of our Ambulance Management system it should get approved by the higher authorities. This integration of GIS/GPS/GSM of ambulance management needs to be funded by Andhra Pradesh state government. In this thesis every corner of the AMS system shows without GIS, we cannot analyze the problems faced by the ambulance on the road network. GIS-network analyst tools are used in our AMS to solve problems faced by ambulance and at the same time using the real-time location information from GPS/GSM. This thesis shows that how well GIS-based AMS will be used to send the routing information to the ambulance driver in real-time. This GIS/GPS/GSM integrated system can be used by other emergency service providers such as police and fire stations to locate their vehicles in densely congested roads. From result we have concluded that this prototype is working well but need further changes after getting into implementation stage in real world. This prototype is evaluated by the GIS-users and concluded that it is very useful for faster transportation of a vehicle considering the real ground situation but also there were some comments on making it further effective by implementing it. Last but not the least, this AMS is useful in faster transport of an accident patient to nearest hospital.

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6.2 Future Work
For faster identification of accident site, we need more detailed database of the landmarks and also more detailed Major & minor roads. To have more detailed database & digital map, we need funding from the Andhra Pradesh government. Andhra Pradesh government is planning make more detailed geodatabase of the Hyderabad city; it will come be prepared in the middle of 2007. AMS is very useful in solving ambulance routing problems, in future it can also be used by emergency service providers. This same prototype can be used by the police and fire authorities to perform the following functionalities. • Find nearest and fastest route from police vehicle to the crime occurred area and also helpful in finding the crime occurred area on the city digital map. Also back to nearest Police station Find the fire spot on digital map and allocating the fire vehicles on fastest route to reach the fire spot.



This AMS system can be implemented in all other cities of Andhra Pradesh, if the detailed geodatabase of every city is available. Hyderabad is a hub of IT Industry and will be the GISbased city in upcoming year. In future this same type of technology can be implemented in the railways for safe transportation. G3 (Geographical information system, Global positioning system and GSM) integrated technology can be used by Indian railway network to meet the following demands. • •


A system for displaying the information A system for locating the position of a vehicle A system for transmitting the information to a control

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Bibliography
[1] G.DereKeneris, J.Garofalakis, J. Prentzas, S.Sioutas, A. Tsakalidis, pp. 269-273. 2000,An information system for the effective management of ambulance , University of patras, Schooling of Engineering, Department of computer Engineering and Informatics, Graphics, Multimedia & GIS lab 26500 Rion , Patras, Greece. [2] M.D Crossland, Wyne, B.E. and Perkins, W.C., 1995, Spatial decision support systems: An overview of technology and a test of efficiency. Spatial decision support systems: an overview of technology and a test of efficacy. Decision Support Systems 14 3, pp. 219–235. [3] Keenan, P., 1996. Using a GIS as a DSS generator. In. Perspectives on DSS, University of the Aegean, Greece, pp. 33–40. [4] Keenan, P., 1998. Spatial decision support systems for vehicle routing. Decision Support Systems 22, pp. 65–71 [5] Marzolf Fabien, Trépanier Martin and Langevin André, 2005, Road network monitoring: algorithms and a case study Computers & Operations Research, In Press, Corrected Proof, Available online 23 May [6] Erkut E, Fenske R, Kabanuk S, Gardiner Q, Davis J. 2001, Improving the emergency delivery in St. Albert. INFOR 2001; 30:416–33. [7] Goodchild MF. GIS and transportation: Status and challenges. Geoinformatica 2000; 4(2):127–39. [8] Ali Akhter Mohammed 2004, Remote sensing & GIS a toll for urban studies- Amenity patterns in Hyderabad (A.P, INDIA), PhD scholar, Dept of geography, Osmania university, Hyderabad, India.E-Mail: [email protected] and [email protected] [9] Jinsoo You and Tschangho John Kim, TOWARDS developing an expert GIS-based travel time forecasting model with congestion pattern analysis, Department of urban and regional planning, University of Illinios at Urbana-Champaign and Seoul National University [10] Dr. Reddy, Jeevananda.S, 2006, Vehicular pollution (In and around Hyderabad), committee: Urban Lakes, Water Bodies H.No.8-2-590/B, Road No.1, Banjara Hills, Hyderabad-500 034 AP India. [11] Maas Gerard, Maggio Mark, Shafie Hadi & Stough Roger, March 11, 1998, Incident management and intelligent transportation systems technology: Estimating benefits for northern Virginia, The Intelligent Transportation Society of America [12] Anthony Harrington and Vinny Cahill 2004, Route profiling Putting Context To Work, Distributed Systems Group, Department of Computer science, Trinity College Dublin

72

[13] Kowtanapanich Wichuda , Tanaboriboon Yordphol, Ruengsorn Danai, Chadbunchachai Witaya 2003 ,Development of emergency medical service support system through GIS and trauma of registry record: A case study of khon kaen Thailand, Journal of the Eastern Asia Society for Transportation Studies, Vol.5, October [14] Misra Ajay, 2005, I.A.S ,A.P Accidents,Transport Commisioner- BRKR bhavan, 6th floor Tankbund Road, Hyderabad-500004, A.P, India [15] Derekenaris .G, Garofalakis .J, Makris .C, Prentzas .J, Sioutas .S, Tsakalidis .A 2000, Integrating GIS, GPS and GSM technologies for the effective management of ambulances, , Computers, Environment and Urban Systems 27 July 2000 [16] Altıntaş K.H. & Nakil Hasta Acil 1997 (For Limited, Ankara,). [17] Emergency Response 2003, http://www.mtbrook.org/Fd/emergenc.htm, (2003 December) [18] Cowen, D.J. (1988). “GIS versus CAD versus DBMS: What are the differences? Photogrammetric Engineering and Remote Sensing. 54(11): 1551-1555. [19] Pons Segui Maria Joana & Perez Ruiz Maurici 2003, NETCOM, vol. 17, n° 1-2, Geographic information system and intelligent transportation systems: technologies used to form new communication networks. [20] THILL, J.-C. (2000). “Geographic information systems for transportation in perspective”. Transportation Research Part C: Emerging Technologies. Vol 8, issue 1-6, pp. 3-12 [21] XU, Y. (2000). “Development of transport telematics in Europe”. GeoInformatica. Vol. 4 (2), June, pp. 179-200. [22] FARRELL, J.A., BARTH, M. (1999). The global positioning system & inertial navigation. New York: McGraw-Hill. [23] Changavalli Venkat (CEO) 2005 of Emergency management research institute (EMRI), Hyderabad, and Andhra Pradesh, India. [24] Thirumalaivasan .D (Senior lecturer in civil engineering, -, Department of civil engineering, Anna University) & Prof. Guruswamy .V (Honorary director, centre for GIS applications, Anna University) Optimal route analysis using GIS. [25]Chuck Reider 2006, Fixing high-crash locations, Nevasa DOT geospatially enables traffic safety [26] ESRI 380 New York street, Redlands, California 92373-8100, USA. telephone: 909-7932853, Fax: 909-793-5953 http://giscenter.isu.edu/what_is_gis.pdf

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[27] Sisi Zlatanova October 18, 2005, A proposed system architecture for emergency response in urban areas [28] Zlatanova, S., 2005, crisis designs, Geospatial Today, May-June 2005, Vol.4, issues 1, pp.30-36 [29] Wang Bin, Wei Qingchao, Tan Qulin, Yang Shonglin, Cai Baigen 2004, Integration of GIS, GPS and GSM for the Qinghau-Tibet railway information management planning. [30] Franklin .C, "An introduction to geographic information systems: linking maps to databases", Database, 1992, 15 (2), pp. 12-21 [33] Keenan .P, "Spatial decision support systems for vehicle routing", Decision support systems, Elsevier, 1998, 22, pp. 65-71. [34] Kaplan, & Elliott .D 1996, Understanding GPS: Principles and applications, Artech house publishers, Boston. [35] Leick .A 1995, GPS satellite surveying, John Wiley & Sons, New York. [36] Parkinson, Bradford .W and Spilker .J 1996, Global positioning system: Theory and practice. Volumes I and II, American institute of aeronautics and astronautics Inc., Washington, DC. [37] Wellenhof, .H & Lichtenegger .B. H, and J. Collins 1994, GPS: Theory and practice, Springer-Verlag, New York. . [38] Wells, D. 1989, Guide to GPS positioning, Canadian GPS associates, Fredericton, NB, Canada. [39]GIS for telecommunication professionals [http://www.esri.com/library/brochures/pdfs/telecomeuro.pdf] in Europe 2000

[40] Bãdut Mircea 2004, A perspective over the location-based applications/services-LBS/LBA, 10th EC GI & GIS workshop, ESDI state of the art, Warsaw, Poland, 23-25 June 2004. [41] Singh K. Sanjay 2005, Journal of Public Transportation, Vol. 8, No. 1, Review of urban transportation in India, Indian institute of technology Kanpur. [42] Moore David, Spatial planning solutions, GIS in emergency planning, A Spatial analysis of ambulance services. [43] Apollo hospitals enterprise limited, 21/22, Greams lane (off Greams Road), Chennai600006, India.

74

[44] Allan B. C. & Gifford F., 1997, An overview to geographic information systems, The Journal of Academic Librarianship, 23(6), 449-46. [45] Gülden Birsen, Erkan Mumcuoğlu, Nazife Bayka 2004, A GIS System for ambulatory transportation, METU, Informatics institute, Information system, 06531, Ankara, Turkey [46] Elizabeth Shafer 2005, ArcGIS® Network analyst, Network-based spatial analysis (http://www.esri.com/library/brochures/pdfs/arcgis-networkanalyst.pdf) [47] Mintsis. G, Basbas. S, Papaioannou. P, Taxiltaris. C, I.N. Tziavos: Applications of GPS technology in the land transportation system, European journal of operational Research 152 (2004) 399–409 [48] Dykes Jason, An Introduction to global positioning systems, VFC, University of Leicester, UK (http://www.geog.le.ac.uk/jad7/gps/intro.html). [49] Liao Ziqi 2003, Taxi dispatching using global positioning systems, Department of finance and decision sciences, School of business, at Hong Kong Baptist University, Hong Kong, May Vol. 46, No. 5. [50] SAN JOSE, Calif, 2002, Research Triangle Park, N.C. - March 18, 2002 http://www.itsa.org/itsnews.nsf/9a6e6f6253e25daa8525690a0055c597/29c4e99634f0a5b785256b 840076ef06?OpenDocument [51] Tokmakidis .K & Tziavos .I.N, 2000, Mapping of Edessa prefecture road network using GPS/GIS, Aristotle University ofThessaloniki, Internal Report. [52] Byman .P, and Koskelo .I 1991, Mapping Finnish roads with differential GPS and dead reckoning. GPS world February, pp. 38–42. [53] G. Mintsis et al. 2000, Development of a prototype automated system for mapping, monitoring and management of the Greek railway network, Research project, Phase A’ report, Thessaloniki. [53] Lakakis .K, 2000,Vehicle navigation in urban environment using GPS technology and geoinformation systems, Ph.D. thesis, Faculty of civil engineering, Aristotle university of Thessaloniki, Thessaloniki. [54] Tzinieris .G & Delikaraoglou .D, 1992, Combination GPS/GIS: A tool for cadastral data collection and management. Bulletin of rural and surveying engineers (1992), pp. 13–27 [55] Monica Chadha 2003, Hi-tech solutions for India's train crashes, BBC correspondent in Delhi, 4 September 10:27 GMT 11:27 UK. [56] F.J. Zarazaga-Soria P.J. A A lvarez, J.A. BanA ares, J. Nogueras, J. ValinA o, P.R. MuroMedrano 2000, Examples of vehicle location systems using, CORBA-based distributed real-time

75

GPS data and services, computer science and system engineering department, University of Zaragoza, MaroAa de Luna 3, 50015 Zaragoza, Spain, 27 July 2000. [57] Chiang .P, Brooks M. Aaron and David .D.H, Weir .H 2004, On the highway measures of driver glance behaviour with an example automobile navigation system, Applied Ergonomics, Volume 35, Issue 3, May Pages 215-223. [58] V. Inman et al. 1996, TravTek evaluation: Rental and local users study, FHWA-RD-96-028, Federal highway administration
[59] Joseph P. DeLorenzo , John C. Allen, Mark A. Jensen 2004, Methodology to Measure the costs and benefits of technology to improve hazardous materials transportation safety and security

[60] Marybeth Luczak, 2004, Executive editor, Railway age September http://www.lat-lon.com/inTheNews/RASept04.pdf [61] Rahnema Moe 1993, IEEE communications magazine April, Overview of the GSM system and protocol architecture [62] Boulmakoul Azedine 2005, Fuzzy graphs modelling for HazMat telegeomonitoring, European journal of operational research [63] Qimin et al, 2003, Design and implementation of WebGIS-based GPS vehicle monitoring system, Institute of Remote sensing applications, Chinese academy of science, Beijing 100101, China. [64] Tsai, Y. (2002, Wang, Z., and Yang, C.-T. "A prototype real-Time GPS/GIS-based emergency response system for locating and dispatching moving patrol vehicles with the beatbased shortest distance method." The third international conference on traffic and transportation studies (2002), Guilin (China), 1361-1368. [65] Lin, C. E., Li, C.-C., Wu, C.-C., Liu, H. S., and Tseng, M. Y. 2003, ”A real time GPRS surveillance system using the embedded system." Industrial electronics society, 2003. IECON '03. The 29th annual conference of the IEEE, 1228-1234. [66] Padmanabhan .J 2001, GPS based vehicle tracking system, advanced micronic devices Ltd, Bangalore (Asian GPS Conference 2001) [67] Dr Kumar Praveen, Reddy Dhanunjaya, Singh Varun 2003, intelligent transport system using GIS, Map India conference 2003, © GISdevelopment.net, and All rights reserved. [68] Kharola1 Singh Pradeep (MD), Gopalkrishna Bipin (Director (S&V)), Prakash (Manager (MIS)), Fleet management using GPS and GIS ,BMTC D.C.,

[69] Hsiung Pao-Ann, Lin Cheng-Yi and Lee Trong-Yen 2003 , Quasi-Dynamic scheduling for the synthesis of real-time embedded software with local and global deadlines, Department of

76

computer science and information engineering national Chung Cheng University, Chiayi, Taiwan, Department of Electronic Engineering National Taipei University of Technology, Taipei, Taiwan

[70] Pavlopoulos Sotiris, Kyriacou Efthyvoulos, Berler Alexis, Dembeyiotis Spyros, and Koutsouris Dimitris 1998, A Novel emergency telemedicine System Based on Wireless communication technology—Ambulance, IEEE Transactions on information technology in biomedicine , Vol. 2, No. 4, December 1998 [71] HATS-2002 (Hyderabad area transportation study), Hyderabad urban development authority (HUDA). [72] Shekhar shashi and Chawla sanjay 2003, Spatial databases a tour, Pearson Education, Inc Upper Saddle River, New Jersy 07458. [73] http://infohost.nmt.edu/~mreece/gps/history.html [74] http://www.fta.dot.gov/research/fleet/its/gis.htm [75] http://www.esri.com/library/brochures/pdfs/arcview91.pdf [76] Schach &Stephen .R 1997, Software Engineering with java, Vanderbilt University [77] Yilin Zhao 1997, Vehicle Location and Navigation System, Artech House, Inc., 685 Canton Street Norwood, MA 02062

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Appendix

User Feedback Questionnaire – AMS
1) Are you able to find the accident site on Hyderabad city road network using AMS user interface? 2) Are you flexible with AMS user interface tools in making analysis? 3) What do you say about menus is sufficient for ambulance management? 4) What do you think about routing tools of Ambulance management system user interface? 5) Is the available data necessary for analyzing the road networks for routing? 6) Is Ambulance management system (AMS) user interface a real solution for handling peak hours? 7) Are you able to perform fastest routing on road networks using Ambulance management system user interface? 8) Are you satisfied from the results of Ambulance management system? 9) As whole what do you think about its implementation on Hyderabad city? 10) Is this interface solving routing problem?

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