The research paper published by IJSER journal is about Traffic Study On Road Network And Programming For Fixing Priority To The Identified Transport Improvement Projects In Salem City, Tamilnadu, India 1

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Traffic Study on Road Network and

Programming for Fixing Priority to the Identified Transport Improvement Projects In Salem City, Tamilnadu, India

T Subramani, R Elangovan, P.K.Kumaresan

Abstract -- Salem is the fifth largest city with a population of 7.54 lakhs (2011) in Tamil Nadu. Fast growth in population and vehicles in these centre have caused congestion in roads for movement of passengers and goods affecting economic development. Local Authorities faced with great difficulties to identify required various road improvement projects. Local authorities have inadequate funds to improve these road networks from all angles at any point of time. Repair or improvement works may have to be under taken on a basis which has to be decided based on socio-economic, administrative, technical, political factors etc., An efficient transportation network is the need of the present urban scenario to tackle the discussed problems. The identified road network selected for the study comprises 162 road links in Salem Corporation. Existing traffic condition, surface condition of carriageway, street lighting, footpath condition and drainage condition in the Salem Corporation area has been studied in detail. Traffic volume count survey was conducted on the idendified 162 road links in Salem Corporation. Identify the type of transport facilities required for the road links. In programming process, priorities are set for project implementation. Even in cases where a formal process of priority setting does not exist, the allocation of organizational and financial resources for the development of some projects over others is an implicit setting of prioriti es. In programming process, priorities are set for project implementation. Even in cases where a formal process of priority setting does not exist, the allocation of organizational and financial resources for the development of some projects over others is an implicit setting of priorities. The important tec hnique devised in this study is working out priority indices based on measures of current conditions of the facilities. There are two approaches for fixing the priorities to se lect road links to improve existing conditions. In the first approach priorities are fixed mainly based on hierarchy of road net wo rk and considering location of road links with weightages assigned to the road links In the second approach priorities are fixed mainly based on location of road links and considering hierarchy of road net work with weightages assigned to the road links.

Index Terms -- Traffic study, programming, transport projects, expert system, Salem city

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1 INTRODUCTION - IMPORTANCE OF

TRANSPORTATION IN URBAN DEVELOPMENT

Transportation contributes to the economic, industrial, social and cultural development of any country. It is well recognized that transport performs a key role in achieving fast economic growth of dev eloping countries. Export and import, industry agriculture defence, social services (health, education), general administration, maintenance of law and order, exploitation of untapped resources, mobility of persons etc., are some of the many areas of activity which are very closely linked to the availability of adequate transportation. Growth of urban areas and nature extent of availability of various classes of labour force are influenced by the extent of development of transport facilities. This growth in term has a cause and effect i9mpact on transport services. Since increase in urban

T Subramani, Professor & Dean, Department of Civil Engineering, VMKV Engg College, Vinayaka Missions University, Salem,India tsm2007@rediffmail.com

R Elangovan, Professor & Principal, Sri Balaji Chockalingam Engg

College, Arni, India tsmcivil2007@gmail.com

P.K.Kumaresan , Professor & Dean, Examination, VMKV Engg. College, Vinayaka Missions University, Salem, India

kums_slm@yahoo.com
population demands better transportation facilities and a services. It may be necessary in the case of a country of India‘s vastness to provide transportation facilities in anticipation of demand, so that the transportation acts as a catalytic agent in development of different sectors.

2 DEFINITION FOR PROGRAMMING

Programming is a technical and political process that established priorities for projects by assessing current and future resource availability in order to stage projects over time. Technical analysis and political considerations are elements of programming that are closely interrelated, with the relative impact of each on any one project decision varying greatly as decision makers seek to satisfy both the relevant transportation policies and the many interest groups involved. There are two tasks which play in important role in the programming process and which are critical to its success
– setting priorities for project selection and determining the availability of funds (Meyer M.D., Miller E.J. 1984).

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3 NEED FOR PROGRAMMNIG

With limited resources available for improvements to the transportation network, much of the interest of decision makers is focused on the programming and budgeting process. The specifics of this process vary from on city or governmental structure to another. In some cases, political decision makers may be interested in the progress of specific projects because these projects are important politically. In other cases decision makers may not be interested in specific projects, but rather in the overall policy that represent.
If there were unlimited resources for transportation projects in a urban centre , there would not be much problem in prioritising the activities. However, the financial and organized resources available for transportation investment are always limited and my in some instances ever be shrinking. In addition to the constraint of declining funding levels, the small number of construction firms in an urban area and the limited ability of government agencies to supervise project construction also limit the number of projects that can be implemented in any one year. Further the limited capacity of government agencies to design facilities or to monitor the design process constrains the number of projects that can reach the programming stage. Giver these circumstances, it becomes necessary to establish priorities for project implementation that is to determine which projects require immediate attention and would receive funding.

4 OBJECTIVES OF THE PRESENT STUDY

1. To examine the existing transport infrastructure facility like roads in the selected Salem urban centre.
2. To conduct Traffic volume survey on the selected 162 road links in Salem Corporation
3. To identify the required road improvement projects in the selected urban centre.
4. To identify the traffic congested road links in Salem
Corporation.
5. To find the extra widening required for the different
road links to carry existing traffic volume.
6. To find the roads which require Traffic management
measures with widening of carriageway.
7. To Rank the problems for prioritization in the order of their magnitude and complexity by using rating values.
8. Prepare the order of priority for taking up road improvement projects with respect to the hierarchy of road net work & location of road links.

5 METHODOLOGY

1. Summarize the findings and recommendations of various previous studies.
2. Identify and collect an relevant information required from local agencies such as demographic trends, map showing the existing land-use and growth trends, income and expenditure, road network details – physical condition, traffic information.
3. Critically evaluate the data to understand the overall
conditions of existing infrastructural facilities in the
Salem urban centre.
4. Conduct traffic volume survey on identified 162 road
links.
5. Analysis the data to identify the magnitude and complexity of the problems, using computer programs
6. Identify the type of road improvement projects require to meet the existing traffic.
7. Prepare a questionnaire and conduct survey to assign ratings to various road attributes.
8. Ranking the problems for prioritization in the order of
their magnitude and complexity by using rating values.
9. Find the order of priority for taking up road
improvement projects with respect to the hierarchy of
road net work & location of road links.

6 STUDY OF PAST AND PRESENT CONDITIONS IN

SALEM CITY

6.1 Salem – General

Salem is the fifth largest city in Tamil Nadu over an area of
91.34 Sq.kms. Salem city is located at distance of 350 kms from a Chennai on the west, and 160 kms from Coimbatore and it got the fifth largest population of 7.54 lakhs as per
2011 census in Tamil Nadu.. It is situated at the trijunction of Bangalore, Trichirappalli and Chennai roads. The City is located at 11 40‘ North and 78 10‘ on the East. The general
topography is plain The city is surrounded by the hills viz. the shervarous and Nagarmalai on the North, The Kanjamalai on the west, the Goodamalai on the East.

6.2 Population growth

The population in Salem has grown at a rate of 23 percent per decade between 1951 and 1971, the rate has been lower for the decade 1971 – 1981 at 17 percent and 14 percent per decade between 1991 and 2011. Table.1 gives the growth of population within the Salem town. Population growth of Salem City Corporation given in Table 1.
Table 1.
Population growth of Salem City Corporation

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Net total

9542

100.0

6.3 Existing Land-Use Structures

The extent of Salem town is 91.34 Sq.km of this the developed area is 4648 Hectares i.e. 48.71 percent of the total area and undeveloped area is 4894 hectares i.e.
51.29 per cent of the total area. The Table 2. gives the existing land use details of Salem City Corporation area
& Figure. 1. is showing the existing land use details of
Salem City Corporation area.
Table 2.
Existing land use details of Salem City Corporation area
Source: Salem Local Planning Autority Records

6.4 Existing Traffic Situation

The traffic in Salem town is heterogeneous in nature comprising of slow moving vehicles such as hand carts, animal drawn vehicles, bicycle and fast moving vehicles such as mini cargo vans, Passenger vans Lorries, buses etc. In the absence of separate lanes for slow moving vehicles and cyclists all the vehicles are found to use the available narrow carriageway. The pedestrian side walks have been provided only near Collectorate. In almost all the main roads vendors occupy the road margins and side walks. Hence the pedestrians are deprived of the use of road margins and side walks and use the carriage way, causing hindrance to the free vehicle movement. This may be noticed more in the central area of the old town comprising of Collectorate and Bus stand complex the main private companies. The intraurban routes are also so operated by number of private operators in addition to government Transport Corporation.

7 IDENDIFIED ROAD NETWORK FOR THE PRESENT

STUDY

Salem district as a whole has only 10,133.7 km. of road, out of which 214.6 km are cement concrete roads, 5098.1 kms. are bituminous surfaced road and the remaining 4821 kms. are water Bound Macadam roads. The unsurfaced road of 2352.7 kms. also exist in the district.

Figure.1. Existing land-use details of Salem City Corporation
Salem Corporation has about 748.13kms. of surfaced roads under its control and maintenance as detailed below. The width of road ranges from 3.5 m to 14.0m in the major road network excluding the lanes and small roads. The details of the various categories of roads with their lengths in the town is show in Table. 3

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Table.3
Types of roads with their length in Salem Corporation

Sl. No	Category	Road length (km)
1	Cement Concrete Super Roads	54.47
2	Black Topped Roads	628.17
3	Wbm Roads	17.04
4	Earthern Road	23.46
5	Others	24.66
	Total length of municipal roads	748.13

The arterial road network of Salem Chosen for the study consists of four major radial corridors originating from the city bus stand. These roads are Attur road in the east, Trichy road and Coimbatore road in the South and Omalur road in the North west. In addition to these, there are a few secondary radial roads. One orbital corridor is identified and it consists of Shandipet road pallapatti main road and court road. Fig.2. shows the identified road network selected for the present study.

8 FIELD STUDIES TRAFFIC VOLUME SURVEY

One of the fundamental measures of traffic on a road system is the volume of traffic using the road in a given interval of time. It is also termed as flow and is expressed in vehicles per hour.

Figure.2. Identified road network of Salem City
Corporation
When the traffic is composed of number of types of vehicles, it is the normal practice to convert the flow into equivalent passenger car units (PCU), by using certain
equivalence factors. The flow is then expressed as PCU per hour.
A knowledge of the vehicular volume using a road network is important for understanding the efficiency at which the system works at present and the general quality of service offered to the road users knowing the flow characteristics, one can easily determine whether a particular section of a road is handling traffic much above or below its capacity. If the traffic is heavy, the road suffers from congestion with consequent loss in journey speeds. Lower speeds cause economic loss to the community due to time lost by the occupants of the vehicles and the higher operational cost of vehicles. Congestion also leads to traffic hazards. Volume counts are, therefore, indicators of the need to improve the transport facilities and are in an invaluable tool in the hands of transport planner.
In order to update the data base of the present existing traffic conditions, Traffic volume counts on selected road links in the urban centre were conducted. The detailed field survey programme was organized for 14 hours between

6 AM -8 PM. The block period is 15 minutes. Traffic volume count survey was conducted on the 162 road links and shown in Figure 3. With the help of these data the peak hour of traffic flow on each road link has been identified.
Figure 3. Traffic volume count survey points on the 162 road links

9 PHYSICAL CHARACTERISTICS

Physical Characteristics of road links in the network studied by field visits during the study and updated to the present existing condition. The study of physical characteristics comprises of surface condition, lighting condition footpath condition and drainage condition.

10 ROAD NETWORK DETAILS

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Road network details collected from directorate of Town and Country Planning, Salem Corporation & Salem Local Planning Authority.

10.1 List of Data collected

The following data have been collected for Salem city
i. Linkwise – road name details
The arterial road network which has been studied is broken into number of links. A link is defined as one- way part of the route between two intersections. The number of road links analyzed in the study is
162.The road links studied in the urban centres are
given in Fig.3.
ii. Linkwise – Physical informations. Following Physical information are collected for 162 road links. The following details of overall road links were collected for the study
Length of road links Carriageway width Footpath width Right of way
Onstreet parking and width covered
Encroached area.
iii. Linkwise Traffic Informations
Linkwise peak hour traffic flow in road links are
calculated from the Traffic volume count survey
iv. Linkwise – Existing physical conditions
Linkwise existing physical conditions, surface
condition, lighting condition, footpath condition and drainage condition in 162 road links are collected.
Surface condition, lighting condition, drainage condition and footpath conditions are graded as very poor, poor and fair. Details of existing landuse along the roadside, type of encroachment and onstreet parking on all road links are observed.

11 PROCEDURE ADOPTED TO IDENTIFY THE

CONJESTED ROAD LINKS

Table.4
The Equivalent Pcu Factors Adopted For Various Vehicles

Vehicle	PCU
Bus, Lorry/Truck	3
Car / Van	1
Two wheeler	0.5
Auto rickshaw	0.6
Cycle	0.4
Cycle rickshaw	1.5
HD cart	4.5
BD cart	8

1. The absolute capacity of a road link is assumed to be between 1300 and 1500 PCU Per hour per lane. Adopting the average of 1400 PCU per land width of 3.5 m, the absolute capacity is taken as 400 PCU per hour per metre width of carriageway.
2. The absolute capacity (400 PCU per metre) multiplied by the ―effective‖ carriageway width gives the actual capacity of the road link. The effective carriageway width has been calculated by reducing the actual width of the carriageway due to different factors affecting the capacity.
3. The factors affecting the capacity are parking, encroachment and landuse. The reduction due to parking and encroachment is shown in Table .5. Predominant land use along the road link affects the capacity and the reduction in capacity due to this factor is shown in Table.6.
Table.5
The Reduction Due To Parking And Encroachment
The extent of the traffic volume on the road links determined from the traffic volume survey conducted at different locations. The equivalent PCU value of the peak hour traffic volume on the road links has been calculated. The equivalent PCU factors adopted for various vehicles are shown in Table.4

12 ROAD LINK CAPACITY

The step by step procedure adopted for calculating road link capacity is as follows.

Table.6.

Reduction in capacity due to land use

Predominant land use Reduction (per cent)

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Open space	0
Residential	5
Institutional	10
Industrial	15
Commercial	30

Calculated the effective width of carriageway considering the above three factors (Parking, encroachment, landuse). The capacity of each road link has been calculated by using the physical information‘s (width of carriageway, parking space, encroachment) is follows.
Effective width of of carriageway = Actual width of carriageway x (1-landuse/ 100))
- Parking space - Encroachment.
Capacity of road link = Effective width of carriageway x 400 PCU

13 LEVEL OF SERVICE OF ROAD LINKS

Comparison of updated traffic volume and capacity of road link give a volume capacity ratio. According to the volume capacity ratio the level of service of the road links are identified. It led to the identification of the degree of congestion in each road link
Table.8. Shows the Level of Service adopted corresponding to the volume capacity ratio. For design purpose Level of Service ―C‖ is suitable for urban streets (Kadiyali L.R 2007).
Table 7.
Level of service adopted in this study

Volume capacity ratio	Level of service
< 0.6	A
0.6 - 0.7	B
0.7 - 0.8	C
0.8 - 0.9	D
0.9 - 1.0	E
1.0 <	F

The road link with Volume Capacity ratio more than 0.8 are classified as congested links. The effective width of carriageway, capacity, volume capacity ratio and Level of Service of all road links in Salem City corporation area calculated.

14 IDENTIFY THE TYPE OF IMPROVEMENTS REQUIRED FOR ROAD LINKS TO CARRY EXISTING TRAFFIC FLOW

Road links which are having volume capacity ratio more than
0.8 are considered as a congested links and these road links
required improvements to carry existing traffic volume. The
following procedure is adopted to identify the required
improvement.
Road links which are having volume capacity ratio more than 0.8 reflect that road link will have insufficient width of carriageway to carry existing traffic. Instead of providing extra widening of carriageway it has been assumed that to prohibit the existing on street parking and remove the encroachment. After removing on street parking and encroachment the effective width of carriageway, capacity and volume capacity ratio have been calculated. If the volume capacity ratio is less than 0.8 then that road link required only removal of on street parking and encroachment to carry existing traffic flow.
If the volume capacity ratio after removing the on street parking and encroachment is more than 0.8 then that road links required a widening of carriageway. For providing extra widening the available extra width has been calculated from right-of- way. If the right of way is not available to widen the carriageway then that road link required traffic management measure.
If right of way have space then widen the
carriageway up to its full width leaving one metre on each
side for pedestrian movements. Again the effective width of
carriageway and volume capacity ratio has been calculated. If
the volume capacity ratio more than 0.8 then that road link required traffic management measure with extra widening. If the volume capacity ratio less than 0.7 than it reflect that extra widening width has been calculated by assuming average volume capacity ratio of 0.75.

15 TECHNOLOGIES USED FOR FIXING PRIORITY TO

IMPLEMENT ROAD IMPROVEMENT PROJECTS

Several efforts have been made to develop comparative analysis techniques to rank project along various dimension. The most popular approach is the use of priority indices based on current condition of the facility. In this study the points assumed to the various grades of attributes are shown in Table.8. The points assumed to the various grades of the attributes are varied from 0.75 to 3. The rating for each attribute like improving surface condition of carriageway, street lighting, footpath condition drainage condition and widening of carriageway are assigned from the experts view.

16 EXPERT SYSTEM

Questionnaire has been prepared for the purpose of collecting experts view on various road improvements to fix the rating to each. Survey has been conducted with experts and their views on various road attributes has been collected. Average value of each road attribute from the survey has been

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assumed as a rating to each road attribute. The rating assigned to each road attribute is shown in Table.9.
Table.8.
Points assumed to the various grades of each road
attributes

S. No	Item		Grade	Points	Variable
1	Surface condition	Very poor	1	X11
		Poor	2	X12
		Fair	3	X13
2	Lighting Condition	Very poor	1	X21
		Poor	2	X22
		Fair	3	X23
3	Drainage Condition	Very poor	1	X31
		Poor	2	X32
		Fair	3	X33
4	Foot path Condition	Very poor	1	X41
		Poor	2	X42
		Fair	3	X43
5	Level of service	F		3	X51
		E		3	X52
		D		3	X53
		C		2.25	X54
		B		1.5	X55
		A		0.75	X56

Table.9.
Ratings assigned to each road attribute

S.No	Item	Rating	Variables
1	Improving the road surface condition	37.4	w1
2	Improving the street lighting	10.9	w2
3	Widening of carriage way for the given traffic volume	15.5	w5
4	Improving the footpath for pedestrian	14.3	w4
5	Improving the drainage condition	21.9	w3

The weigtage of the each road link has been calculated by using points allotted to various grades of road attributes and rating assigned to the each road attributes from the
survey. Weightage of each road link has been calculated as follows.
Weightage = (x11\x12\x13)w1 + (x21\x22\x23)w2 + (x31\x32\x33)w3

+ (x41\x42\x43)w4 + (x51\x52\x53)w5

Where
x11,x12,x13............... x55 = Points allotted to various grades of each road attributes
w1 ,w2, w3 ,w4, w5 = Ratings assigned to the various attributes from the survey.
If the the road link have all road attributes with very poor or poor grade, the the weightage of the road link should be very low of 96.125. If the road link have all road attributes with fair grade, the weightage should be very high of 300.

17 METHODS ADOPTED FOR FIXING PRIORITY TO

IMPLEMENT ROAD IMPROVEMENT PROJECTS

In this study two approaches are considered to fix the priority for Implementing road improvement projects.

17.1 PRIORITY BASED ON HIERARCHY OF ROAD

NETWORK

In this approach the priority for selecting road links to implement road improvement projects are fixed on the basis of hierarchy of road network. According to the hierarchy of road network following priority is assumed.
Priority 1. Radial roads in CBD area with low weightage.
Priority 2. Radial roads in Fringe area with low weightage.
Priority 3. Orbital roads in CBD area with low weightage.
Priority 4. Orbital roads in Fringe area with low weightage.
Priority 5. Other roads in CBD area with low weightage.
Priority 6. Other roads in Fringe area with low weightage.
As per above priority basis the priority has been fixed to the road improvement projects of road links in Salem corporation area. The of priority for selecting road links to implement the road improvement projects as per hierarchy of road network is given in Table.10.
Table.10

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Order Of Priority For Implementing Road Improvement Projects In Salem Based On Hierarchy Of Road Network

Priority No	Link Number	Type	Location Type	Total weightage
1	140	Radial	CBD	135.625
2	146	Radial	CBD	147.1
3	139	Radial	CBD	147.25
4	52	Radial	CBD	157.525
5	55	Radial	CBD	157.525
6	79	Radial	CBD	162.125
7	85	Radial	CBD	180.625
8	145	Radial	CBD	181.975
9	86	Radial	CBD	184.025
10	2	Radial	CBD	191.525
11	67	Radial	CBD	191.525
12	123	Radial	CBD	191.525
13	124	Radial	CBD	191.525
14	43	Radial	CBD	194.2
15	44	Radial	CBD	194.2
16	138	Radial	CBD	196.275
17	1	Radial	CBD	203.15
18	122	Radial	CBD	205.825
19	60	Radial	CBD	206.55
20	61	Radial	CBD	206.55
21	66	Radial	CBD	214.775
22	100	Radial	CBD	217.3
23	125	Radial	CBD	217.3
24	126	Radial	CBD	217.3
25	127	Radial	CBD	217.3
26	45	Radial	CBD	217.45
27	97	Radial	CBD	217.45
28	121	Radial	CBD	217.45
29	115	Radial	CBD	227.725
30	154	Radial	CBD	228.925
31	46	Radial	CBD	229.075
32	47	Radial	CBD	229.075
33	42	Radial	CBD	231.6
34	49	Radial	CBD	231.6
35	128	Radial	CBD	231.6
36	129	Radial	CBD	231.6

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122	11	Orbital	Fringe	205.825
123	16	Orbital	Fringe	206.55
124	30	Orbital	Fringe	206.55
125	33	Orbital	Fringe	206.55
126	19	Orbital	Fringe	216.1
127	64	Orbital	Fringe	218.175
128	18	Orbital	Fringe	253.5
129	20	Orbital	Fringe	253.5
130	21	Orbital	Fringe	253.5
131	22	Orbital	Fringe	253.5
132	34	Orbital	Fringe	276.75
133	35	Orbital	Fringe	276.75
134	36	Orbital	Fringe	288.375
135	37	Orbital	Fringe	288.375
136	38	Orbital	Fringe	288.375
137	54	Others	CBD	157.525
138	84	Others	CBD	169.725
139	92	Others	CBD	180.625
140	81	Others	CBD	184.025
141	83	Others	CBD	184.025
142	80	Others	CBD	194.925
143	94	Others	CBD	194.925
144	98	Others	CBD	203.15
145	93	Others	CBD	203.875
146	95	Others	CBD	205.825
147	96	Others	CBD	205.825
148	82	Others	CBD	207.275
149	120	Others	CBD	229.075
150	99	Others	CBD	254.85
151	119	Others	CBD	288.375
152	161	Others	Fringe	157.525
153	162	Others	Fringe	157.525
154	23	Others	Fringe	205.825
155	24	Others	Fringe	205.825
156	101	Others	Fringe	218.025
157	102	Others	Fringe	218.025
158	103	Others	Fringe	232.325
159	106	Others	Fringe	254.225
160	107	Others	Fringe	254.225
161	105	Others	Fringe	265.85
162	104	Others	Fringe	277.475

17.2 PRIORITY BASED ON LOCATION ROAD LINKS

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In this approach the priority for selecting road links to implement road improvement projects are fixed on the basis of location of road link. According to the location of road link following priority is assumed.
Priority 1. Radial roads in CBD area with low weightage.
Priority 2. Orbital roads in CBD area with low weightage
Priority 3. Other roads in CBD area with low weightage.
Priority 4. Radial roads in Fringe area with low weightage.
Priority 5. Orbital roads in Fringe area with low weightage.
Priority 6. Other roads in Fringe area with low weightage.
As per above priority basis the priority has been fixed to the road improvement projects of road links in Salem corporation area. The of priority for selecting road links to implement the road improvement projects as per location of road link is given in Table.11.
Table.11.
Order of priority for implementing road improvement
projects in salem based on location of road link

Priori ty No	Link Number	Location	Type	Total Weighta ge
1	140	CBD	Radial	135.625
2	146	CBD	Radial	147.1
3	139	CBD	Radial	147.25
4	52	CBD	Radial	157.525
5	55	CBD	Radial	157.525
6	79	CBD	Radial	162.125
7	85	CBD	Radial	180.625
8	145	CBD	Radial	181.975
9	86	CBD	Radial	184.025
10	2	CBD	Radial	191.525
11	67	CBD	Radial	191.525
12	123	CBD	Radial	191.525
13	124	CBD	Radial	191.525
14	43	CBD	Radial	194.2

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57	150	CBD	Radial	266.475
58	5	CBD	Radial	274.075
59	110	CBD	Radial	274.075
60	111	CBD	Radial	288.375
61 62	112 113	CBD CBD	Radial Radial	288.375 288.375
63	56	CBD	Orbital	157.525
64	57	CBD	Orbital	157.525
65	78	CBD	Orbital	162.125
66	91	CBD	Orbital	180.625
67	90	CBD	Orbital	184.025
68	58	CBD	Orbital	194.925
69	59	CBD	Orbital	194.925
70	159	CBD	Orbital	194.925
71	160	CBD	Orbital	194.925
72	87	CBD	Orbital	205.825
73	88	CBD	Orbital	205.825
74	89	CBD	Orbital	205.825
75	158	CBD	Orbital	206.55
76	157	CBD	Orbital	218.175
77	156	CBD	Orbital	255.575
78	54	CBD	Others	157.525
79	84	CBD	Others	169.725
80	92	CBD	Others	180.625
81	81	CBD	Others	184.025
82	83	CBD	Others	184.025
83	80	CBD	Others	194.925
84	94	CBD	Others	194.925
85	98	CBD	Others	203.15
86	93	CBD	Others	203.875
87	95	CBD	Others	205.825
88	96	CBD	Others	205.825
89	82	CBD	Others	207.275
90	120	CBD	Others	229.075
91	99	CBD	Others	254.85
92	119	CBD	Others	288.375
93	29	Fringe	Radial	124.725
94	143	Fringe	Radial	147.1
95	144	Fringe	Radial	147.1
96	137	Fringe	Radial	147.975
97	51	Fringe	Radial	169.725
98	69	Fringe	Radial	169.725

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Traffic Management
3. Measure required with 23 extrawidening of
carriageway

17.3 CONCLUSION

An important product of the analysis is the development of a program which outlines the improvements to be carried out. From the study made, the type of improvement required to the road links to carry the existing traffic flow has been identified. Total number of road links requiring various types of improvements in Salem city corporation area to carry existing traffic flow is shown in Table.10.
Table.10.
Types of improvements required to carry existing traffic flow
In programming process, priorities are set for project implementation. Even in cases where a formal process of priority setting do s not exist, the allocation of organizational an d financial resources for the development of some projects over others is an implicit setting of priorities. The important technique devised in this study is working out priority indices based on measures of current conditions of the facilities. There are two approaches for fixing the priorities to select road links to improve existing conditions.
In the first approach priorities are fixed mainly based on hierarchy of road net work and considering location of road links with weightages assigned to the road links. In the second approach priorities are fixed mainly based on location of road links and considering hierarchy of road net work with weightages assigned to the road links.

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