Hide Notes 

Slide 1: A Decision Support System For Land Use Activity Changes Using Data Gained from The Intelligent Transportation Systems Arch. Ahmed M. El-Geneidy Department of Architecture, Faculty of Engineering, Alexandria University Dr. Hany M. Ayad Department of Architecture, Faculty of Engineering, Alexandria University Dr. Nadia S. El-Baghdady Department of Architecture, Faculty of Engineering, Alexandria University Dr. Yousry A. Azzam Department of Architecture, Faculty of Engineering Alexandria University Abstract: The majority of discussion in literature concerns the environmental impacts of Intelligent Transportation Systems (ITS) on air quality, noise and energy. Land use and social-equity environmental impacts are discussed to a limited extent in such literature. In the land use decision-making process, a frequent question, which concern a new project, are "Will it create more congestion?" and "What effect will the project have on the quality of roads?". To answer the previously mentioned questions a proposed Decision Support System (DSS) is adopted to avoid future transportation problems that might emerge from such changes in land use activities. The DSS mainly aims at making traffic impact analysis for changes in land use activities based upon real time data. A methodology for the interaction between data gained from ITS and changes in land use activities is proposed. This methodology can be applied for one or more land plots, and for different types of activities. Also a proposed flowchart for software that can be used in such interaction is demonstrated. Decision-makers, landowners, planners, and investors can use the previously proposed software in making decisions towards changes in land use activities, which might affect transportation systems. Keywords: Land-use, Decision Support System, Transportation Planning, Intelligent Transportation Systems.
Slide 2: 1. Introduction The main problem in several Egyptian cities is the unplanned change and accumulation of land-use activities to the existing urban structure, which in term causes the generation of unforeseen large capacity of vehicle trips. Due to inadequacy of the streets to accommodate such new trips and the absence of suitable parking spaces, illegal parking and traffic congestion are inevitable. Traffic congestion is a familiar problem that seems to affect just about any place with a road and cars. Sundeen (1998) remarks that in the United States annually traffic congestion causes an estimated 10 billion US dollars loss in productivity, wastes about two billion hours and consumes an additional one billion gallons of gasoline. Traffic congestion also diminishes air quality, creates a variety of safety hazards, often discourages tourism, and can reduce business information. The connection between land-use and transportation is a fundamental concept. Every thing that happen to land-use activity has a transportation implication. Wright and Ashford (1989) describe the land-use transportation cycle as shown in figure (1). This cycle will keep going on unless any one (the planner, decision maker ..etc) interferes in it. The interaction between transportation and land-use changes is often termed traffic impact analysis, in another term, site impact traffic evaluation (Beimborn, 1995) It is assumed that in order to forecast illegal parking and traffic jam problems, an evaluation of traffic impact should be conducted for any change in land-use activities. In turn, the traffic impact analysis usually relays on large amount of data that need to be compiled, updated in a regular basis and analyzed for decision making. Change Land-use Increased land value Increased Trip Increased accessibility Added transportation facilities Greater traffic needs Figure (1) Land-use and transportation cycle
Slide 3: This paper aims at building a decision support system (DSS) applicable in the field of landuse management. More specifically, the following objectives are required to be achieved: • Suggest a DSS frame work outfitted to any city, in order to give the decision-maker a tool to evaluate the impact of land-use changes on the transportation systems. The DSS aims at making traffic impact analysis to study the traffic generated from changes in land-use activities based upon real time data. • Propose a computer base methodology based on (a) data and standers related to different land-use requirements in the city and (b) Information collected through an intelligent transportation systems (ITS). • Insure the applicability of methodology in different events that could be required by the analysts such as the changing number or size of land plot, and the different combinations of land-use types. • Apply the proposed DSS frame work in one of the Egyptian cities (Alexandria) using real time data and existing land-use activities. It is intended that the proposed methodology should have a friendly based computer interface in order to assist decision maker, land owners, planner, or investors in making decisions about land-use allocation and its consequences on transportation systems. 2. Intelligent transportation systems (ITS): An overview 2.1 ITS Definitions ITS is a broad term that can refer to several definitions and applications. In planning, the term ITS refer to transportation systems which apply emerging hard and soft information systems technologies to address and alleviate transportation congestion problems. For example using advanced surveillance systems; the early stages of traffic bottleneck situation can be detected, and traffic can be directed to other routes to mitigate the congestion and to provide faster and more efficient routes for travelers. New technologies enable this type of surveillance and guidance response to occur in real time, and therefore, to allow potential congestion situations to be addressed before they develop in traffic jams (Johnson, 1999). ITS scope and aims were studied by Mohaddes (2000), Romine (1998), Goehring (1997), and others. ITS can be defined as “ The application of information and communication technologies to the planning and operation of transportation systems”. One ITS first
Slide 4: emerged on the market community often used individual; technologies to provide one particular service. As ITS grew more sophisticated communities linked technologies and applications so that individual systems could provide many services. The successful development of ITS depends on the capability of incorporating a vast amount of information about the location which generate travel as well as realistic representation of transportation network in which travel occur (Golledge, 1996). ITS is the future technologies that we deal with, sooner or later, in our transportation system (Mcqueen and Mcqueen, 1999). Using ITS technologies decision maker can give quick transportation decision based on specific data. ITS enables the decision makers to evaluate their decisions. The huge amount of data gained from the ITS mainly from the transportation management center are useful in various fields that affect the transportation systems (Ben Akiva, 2000). 2.2 ITS subsystems To achieve the goals of applying ITS Mast (1998) has subdivided the ITS into six interlocking technology subsystems where together they form the ITS. ATIS. Advanced Traveler Information Systems include a variety of systems that provide real-time in-vehicle information to drivers. AVCS. Advanced Vehicle Control Systems that aid the drivers in controlling their vehicle particularly in emergency situations. CVO. Commercial Vehicle Operations address the application of ITS technologies to the special needs of the commercial roadway vehicle. ATMS. Advanced Traffic Management Systems monitor, control and manage traffic on streets and highways to reduce congestion (will be discussed late in this part). ARTS. Advanced Rural Transportation Systems include systems that apply ITS technologies to the special needs of rural systems and include emergency notification and response. APTS. Advanced Public Transportation Systems enhance the effectiveness, attractiveness, and economics of public transportation and include fleet management. Each of the previous technology areas has its factors that affect its performance. They interact with each other so as to build the ITS as shown in Figure (2). The presence of any of the previously mentioned systems can be the core of building an ITS. To build an ITS it is not a must to have all the subsystems.
Slide 5: ATIS AVCS ATMC CVO ARTS APTS ATMS ITS Figure (2) ITS areas of technology. The ATMS is the heart of the ITS. The transportation planners mainly deal with data gained from the ATMS. ATMS provides new technologies for controlling traffic and for communicating information to the vehicles and drivers. The Traffic Management Center (TMC) is the primary ganglion in this network of data sensing, information processing, communication, and control devices. From the TMC human operators and central computers monitor that traffic condition and carry out any measures necessary to promote smooth traffic flow. To feel the importance of such center, a typical advanced traffic management system is shown in Figure (3) (Kelly and Folds, 1998). Traffic speed and density Roadway condition Weather Incident status Infrastructure Traffic speed Traffic volume Traffic diversions AHS control Sensor Monitoring & Fusion Event Plans Preplanned Events Voice / video Data from Outside resources Advanced Traffic Management Center Planning Training Decision Making Option Generation Decision support Communication Within TMC Response analysis and selection Traffic Control Data Dissemination Incident reports from public or media Info from other modes Incident reports from police Request to close lanes/ streets Complaints about maintenance Improved routing (ATIS, CVO). Decrease demand (ATMS). Dispatch emergency vehicles Data to smart vehicle (AVCS) Data to other TMCs (ATIS, CVO, AVCS) Figure (3) The typical advanced traffic management system.
Slide 6: The TMC is the main component of ATMS that work as the heart of ITS. It links between the different components of the ITS and it also links between different ITS programs in other places so as to coordinate between them. The main functions of TMC is summarized in the following points: • • • • • Control vehicle motion, speed, and access. Influence vehicle routes, trip planning, and travel mode selections. Collect and store traffic data, incident data, and road toll data. Train TMC staff. Plan future responses and activities. The planners mainly are interested in the stored data in the TMC. It gives them a complete figure of the transportation system. These data can be used in various fields of urban planning. So if we need to talk about the data gained from ITS we have to deal with the TMC to obtain data from it. 3. Intelligent transportation systems (ITS) and land-use planning: A Methodology In land-use decision-making process a frequent question concerning a new project is “Will it create more congestion?” or “what effect will the project have on the quality of road?” and “Will the project in this location let people use non-auto travel to get their destination?” In literature review, little is known about exactly how ITS technology would function and how it would interrelate with land-use. During the preliminary investigation for the Orlando Metroplan Project, it was found that the information and researches required to analyze the interaction between the land-use and ITS was insufficient to carry out the analysis (Grovdhal and Hill, 2000). Miller (1999) comments that our understanding of transportation/land-use interaction and how it is affected by current technologies is limited. The work presented here attempts to formulate a routine that interrelates data gained from ITS and information collected about the possible changes in land-use activities. The framework is based on data acquired from the following sources: 1. ITS data (specially data gained from TMC such as vehicle per hour per lane in each direction, average speed, and parking) 2. Changes in land-use activities, creating new trip generation and new parking demands. ( any place in the world has its own standards in the trip generation, parking demands for each land-use activities)
Slide 7: 3. Trip generation standards ( any place in the world has its own standards for trip generation. For example these standards can be obtained from ITE trip generation hand book which is applied specially for the United States) 4. Parking demand standards (any land-use has its own standards for parking demands. For example these standards can be obtained from ITE parking hand book which is applied specially for the United States) Figure (4) presents the model diagram for the proposed decision support framework, which can be summarized as follows: 1. 2. 3. Select the desired land plot(s) to be analyzed in a study area Determine land-use activities code for the land plot(s) Based on Standards, the land-use activities under examination will generate a specific amount and type of traffic that could be referred as a “trip value”. 4. Determine trips generated from and to the existing land-use activities, as well as associated parking demands. Using the travel demand forecasting standards. 5. Meanwhile, an ITS will serve to monitor the existing condition in the study area and generate its own data table for the whole study area. 6. Subtract trip values generated from steps 3 and 4, from the ITS data table. The resultant ITS data table indicates the hypothetical condition of the study area without the influence of the selected land plot(s) on the transportation system. 7. Determine the proposed land-use activity that will replace the existing one on the selected land plot(s). Subsequently, a new land-use activity code is generated based on several variables such as the number of users (in case of restaurants), number of dwelling units (in case of residential uses), or gross floor area (in commercial uses). The previous variables as well as other factors are described here as the “independent variables”. 8. Calculate the new trips generated from and to the selected land plot(s). Repeat the same procedure in order to calculate the parking demand. 9. Add trip values generated from step 8, to the ITS data table. The resultant ITS data table indicates the expected condition of the study area with the influence of the selected land plot(s) and proposed land-use activity on the transportation system. 10. Present the results in form of thematic maps and tables that estimate the consequences of any change in land use on the transportation system in the selected study area.
Slide 8: The previous framework is further explained using the proposed low-level flow chart presented in figure (5). The flow chart serves as a basis to develop the computer-based interface. Select The Land Plot Select another land plot Parking, Trip Generation Hand Book and travel demand forecasting Code Determine Land use code ITS Data Determine the distribution of the Trip Value Subtraction ITS existing Data Tables trip generated in all the streets from the old land use activities. Code Determine the new land use activities and the values of the independent variables. Selection New ITS estimated Data Tables Trip Value Determine the distribution of the trip generated and parking demand in all the streets from the new land use activities. Addition Final ITS simulated data tables with the old trips and parking subtracted and the new trips and parking added Present the estimated situation after the land-use activity change in the sort of maps and tables. Figure (4) ITS and land-use activity model diagram
Slide 9: X=0 Start N=0 Enter the land plot Code Determine the land plot location and activity Trip Generation table The effectiveness of the entered land-use activity X=0 Determine the streets that are affected from the entered land-use functions according to the distance from the land plot and according to the entered functions. Also the percentage of effectiveness on each street is determined. No Let T=T1 X=0 Determine the factors affecting each land-use activity Yes No No If code=0 N=0 Yes Subtract the trip generation generated from the land-use functions in the streets data table according to effectiveness of the old functions from T so as to build T1 Change N=1 Yes Enter new land-use functions code Add the trip generation generated from the land-use functions to the streets data table T1 according to effectiveness of the functions to form T2. Delete or Change Delete Rename T2=T1 Yes X=1 Is there more land plots? No Finish & Represent the streets data table T1 as a theme on a map. No Is there over loaded streets? Yes Highlight the overloaded streets with a new color in T1. Figure (5) ITS and Land-use Model Flow Chart
Slide 10: 4. Implementation 4.1. Alexandria Transportation System Alexandria is the second largest city in Egypt, and it is by far the most important exporttrading center of the country. Because of the presence of water bodies and valuable agricultural lands bounding the region, the city extends for more than 35 kilometers in length, and is limited to less than 5 kilometers in width (Figure 6). Figure (6) Alexandria map. The Alexandria transportation system consists mainly of the road network, which supports both private and public vehicles, and the public transportation network (tramway and trains). Due to the linear composition of Alexandria and the increasing population pressures on the transportation networks, the city is undergoing serious traffic jams and parking demand problems. As a response, the General Organization for Physical Planning (1997) defined five objectives to be considered in the formulation of an action plan: 1. Improve the socioeconomic conditions by making adequate links between the major urban and suburban centers that support the expected urban growth. 2. 3. 4. 5. Alleviate congestion, reduce the cost of travel, and allow for safety trips. Increase the public transportation capacity to support increasing future demands. Improve roadway conditions Develop a strategic framework for future land-use allocation.
Slide 11: 4.2. DSS Model Implementation In order to carry out the study, a site that represents a prototype of Alexandria east district was selected. The site is characterized by mixed residential and other uses, as presented in the land-use activity map (figure 7). The area is approximately 320 000 square meters, and is bounded from the east and west with two main roads. From north and south, the area is penetrated by the two main arterial roads in Alexandria, El-Horia Avenue and El-Geish Avenue. Figure (7) Selected area land-use map. Prior to the model implementation, a site survey was conducted during the period from May to December 1999. The purpose of the survey was to: (a) update the land-use map, (b) determine the factors affecting the transportation system and ITS of the area, and (c) to
Slide 12: simulate an ITS for the study area. The gathered data was compiled in both tabular and spatial forms using both the Arcview GIS and Microsoft Excel software. A serial number code from 1 to 375 was assigned for each land plot. Another serial number code from 1 to 56 was assigned for each street the land plot is facing. For land-use activities, a third code was assigned, consisting of four digits category. Each digit represents a different level of land-use activity. 5. Intelligent Transportation Systems (ITS) and Land-use Planning: The Computer Based Interface The next objective to be achieved is to develop the computer-based interface. The interface is developed using the Visual Basic tools provided with the Microsoft EXCEL software and relies on its built-in tables and macros features to build the required database. The interface benefits also from the powerful ability of the ArcView GIS software in presenting and relating both spatial and tabular data, and links it with the information gained from the ITS. The Interface has two folded design levels. The high-level is the user interactive level. It is designed to be both flexible and easy to use. The calculations and coding that make the software work efficiently are executed in the low-level. When running the software the user passes through many processes. The computer interface gives the users two options in changing the land-use activities. The first option of changing the existing land use activities is that the user can change the land-use activities using the change in the independent variables of the land-use activities without any guidance to his entries. The second is the guided change, where the user is guided through the whole process of change. In the guided change the user has the capability of following the building regulations in the study area or even setting up new building regulations. The guided method has many forms and is sophisticated in its calculations. Figures 8,9 and 10 explain the interrelationship between the different rules in the high-level part of the interface, the guided data entry in design forms, and the method of displaying the final data results.
Slide 13: START FORM Start form Scratch Open existing file Set all the Use previously changed tables and variables SELECTION FORM system variables as default Select another plot Select Maps in Arc view GIS land plot Enter land plot code View land plots Excel Table with all changeable plots displayed in it. PLOT DATA FORM Select another plot Manual land-use change Guided land-use change Print the existing plot data Quit the program MULTI USE CHANGE FORM System variables & Guided Number of dwelling units in apartment Number of offices in office building Number of rooms in hotel change Number of seats in restaurant Gross floor area in shopping center Number of beds in hospital FINAL FORM FINAL CHANGED DATA Exit Figure (8) Computer based interface diagram.
Slide 14: Plot Form Guided multi use change Form Variable Form Parking and garage variables Variable Change Building Height regulations Select new type of building Apartment building Shopping Center Office building Change FAR Change Floor Area Ratio variable Form Hospital Hotel Back to building form Building Forms Enter area of dwelling unit Multi use Apartment building Multi use Office Building with restaurants and shopping center Hotel Hospital Multi Shopping Center with restaurant and offices Manual Entry Form Number of dwelling units in Apartment building Number of Offices Number of rooms Number of beds Gross floor area Final Form Final Changed Data Figure (9) Guided change schematic diagram
Slide 15: Multi use Selection change Form Form Multi use change form Final Form Save Exit View data Select another land plot Data display Form View a specific time, in a specific day and specific season View a specific table (Trip generation, parking) View a specific street data or view more than one street View affected streets by the last change in land use functions Data display Forms Display specific time form Display Table form Display specific street form Display Changed streets form Data tables View the desired data table Exit Figure (10) Data display schematic diagram
Slide 16: The proposed software interface was then applied to change some land-use activities on an existing land plot. An existing single-family house was proposed to be demolished and replaced by a new apartment building and a shopping center. Figure (11) represents a summary of the results achieved from the interface application. It shows the effect of landuse changes on the traffic density of an adjacent street, during different times of the day, and on selected dates. A similar graph was prepared for parking demands. It was obvious that the proposed change in land-use will considerably affect the parking demands and transportation densities during the peak hours, exceeding the carrying capacity of the selected street. Such a change will inevitably cause a traffic jam and illegal parking. 180 160 140 120 100 80 60 40 20 0 2\3 7\8 14 \ 15 Sunday 17\ 18 21\22 2 \ 3 7 \ 8 14 \ 15 Monday Summer 17\ 18 21\22 2 \ 3 7\8 14 \ 15 Thursday 17\ 21\22 2 \ 3 18 7\8 14 \ 15 Friday 17\ 18 21\22 2 \ 3 7\8 14 \ 15 Sunday 17\ 18 21\22 2 \ 3 7 \ 8 14 \ 15 Monday Winter 17\ 18 21\22 2 \ 3 7\8 14 \ 15 Thursday 17\ 21\22 2 \ 3 18 7\8 14 \ 15 Friday 17\ 18 21\22 Sharawi Street Existing VHLD 2 Step 2 Figure (11) a study of the effect of land-use change on the traffic in a selected street within the studied area. The proposed computer interface was then used to change land use activities in different land plots in the study area. The summary of results was presented in several sheets that may assist decision-makers about what activities in the city should be kept, replaced, or removed, in order to alleviate transportation system problems, or at least to avoid more congestion.
Slide 17: 6. Conclusions and Recommendations In the present study, a DSS model framework that relies on data gained from ITS, land use information, trip generation standards, and parking demand standards is proposed and tested on a selected study area. The proposed method benefits from the data gained from ITS in the field of urban transportation planning. It provides decision-makers with a firm basis to formulate new building regulations in accordance with the future transportation system policy. Specific results can be summarized as following: 1. The proposed methodology can be used in further research in determining the different effects of land-use changes on air quality, noise pollution, social effects, and travel cost. This can be achieved through the data gained from the methodology after the changes. 2. The study demonstrates that the lack of information on transportation systems in Egypt could be accurately accomplished by the introduction of an Intelligent Transportation System that can provide fast and accurate information required for planning purpose. 3. The computer software interface developed here can be applied to different case studies, and is flexible to accept changes in trip generation and parking standards, as well as changing criteria for land-use activities. 4. It is necessary to prepare a national program of research and development for long term ITS deployment. It is also important to appreciate any change in the developing practice planning tools, policies, and theories of land development as they are related to transportation. 5. When combining ITS with other technologies it might have benefits in improving transportation in the community. It will be important to assess how those improvements can be integrated with land-use policies to better manage growth in transportation demands.
Slide 18: 7. References Beimborn, E. A. (1995). A Transportation modeling primer (pp.1–2). Wisconsin-Milwaukee: Center for Urban Transportation studies, University of Wisconsin-Milwaukee. Ben Akiva, M. (2000). Modeling and simulation for dynamic transportation management system (pp. 1-4). Massachusetts: MIT, ITS program. Goehring, J. B. (1997). Linking technologies for commercial vehicle operations: what will the future hold. Transportation series No 6, National Conference of State Legislatures, (pp. 11 –15). USA. Golledge, R. G., Kwan, M. P., Seigal, D. (1996). Information representation for the driver decision support system (pp.2– 4). USA: TRB. Grovdhal, D. L., Hill, E. T. (2000). Regional planning and ITS: effect on land-use and society. ITE journal (pp. 34 – 38). Johnson, C. M. (1999). Intelligent Transportation Systems (ITS). Domestic annual report, (pp.1-4). Kelly, M. J., Folds, D. J., (1998). The advanced traffic management center. In Barfield, W., Dingus, T. A., Human Factors in Intelligent Transportation Systems, London, Lawrence Erlbaum Associates publishers, (pp. 166). Mast, T. (1998). Introduction to ITS. In Barfield, W., Dingus, T. A., Human Factors in Intelligent Transportation Systems, London, Lawrence Erlbaum Associates publishers (pp. xv). Mcqueen, B., Mcqueen, G. (1999). Intelligent Transportation System Architecture, First edition (pp.441-446). Massachusetts: Artech house Inc. Mohaddes, A. (2000). Council report summary innovative traffic control equipment, procurement methods. ITE journal (pp.44 – 49). Romine, R. (1998). What is ITS. ITS America, (pp.1 – 2) Sundeen, M. (1998). Intelligent Transportation Systems. NCSL, Transportation Review, (pp.1 – 6).
Slide 19: The General Organization for Physical Planning, The Ministry of Housing, Utilities and Urban Communities (1997). General planning for Alexandria up to year 2017, Part three Infrastructure studies (pp. 36-37). Egypt. Wright, P.H. and Ashford N. J. (1989). Transportation Engineering Planning and Design, Third edition. (pp. 221-222). New York: John Wiley & Sons.