This course provides an introduction to transportation engineering through five modules: transportation systems engineering, transportation planning, geometric design, pavement design, and traffic engineering. The objectives are to present a systems approach to transportation and describe the basic characteristics and models used in transportation planning, geometric design of highways, pavement design, and traffic engineering parameters and controls. The course aims to give students an overview of the interactions within transportation systems and the engineering concepts used in their planning, design, and operation.
This document discusses traffic engineering and road user characteristics. It defines traffic engineering as dealing with planning and design of roads and highways, as well as traffic operation related to safe and efficient transportation. The key points covered include:
- The scope of traffic engineering includes traffic studies and analysis, traffic control and regulation, planning, geometric design, and administration.
- Traffic characteristics and road user characteristics are important to study, including physical, mental, and emotional traits of drivers.
- The functions of a traffic engineer include data collection and analysis, transportation planning, traffic design, and measures to operate and regulate traffic.
- Road user behavior is influenced by physical, psychological, and environmental factors. Reaction time and visual abilities
The document summarizes the results of a traffic survey conducted by a student group. It includes:
1) The objectives of studying vehicle composition, traffic stream properties, and directional distribution.
2) Findings from the survey such as the predominant vehicle type being personal vehicles and the directional distribution showing more traffic from Panthapath to Russell Square.
3) Limitations of the study related to resources and time constraints.
The document discusses a traffic volume study conducted at Russell Square in Dhaka. It defines key terms like average daily traffic (ADT) and level of service (LOS). Data was collected manually over three hours and analyzed to find a service flow rate of 1,131 passenger car units per hour, indicating an LOS of D. The average daily traffic was calculated as 16,080 passenger cars with an annual average of 22,432. Traffic movement was found to be nearly equal in both directions.
This document discusses traffic characteristics and engineering. It defines traffic engineering as dealing with planning and designing streets and highways for safe, efficient traffic flow. Road users and their physical, mental, psychological characteristics are examined, as well as vehicles' static properties like weight and dimensions, and dynamic properties like speed and braking. Traffic surveys study these characteristics to determine road geometry and controls. Perception, intellect, emotion and volition times that make up a driver's total reaction time are also outlined.
The document defines different types of traffic volumes used for transportation planning and design. Daily volumes like average annual daily traffic (AADT) are used to establish trends over time. Hourly volumes like the peak hour volume are most important for design and operational analysis. Within the peak hour, the peak 15-minute volume and peak hour factor (PHF) account for fluctuations in flow. Sub-hourly volumes below 15 minutes are also sometimes analyzed.
Chapter 6 Fundamentals of traffic flowFayaz Rashid
The document discusses fundamental principles of traffic flow, including the primary elements of traffic flow such as flow, density, speed, and headway. It describes flow-density relationships and the fundamental diagram of traffic flow. Mathematical models for describing macroscopic traffic flow relationships are presented, including the Greenshields model relating traffic density to speed. The primary elements, flow-density relationships, and Greenshields traffic flow model are summarized for understanding traffic flow characteristics.
this is a brief introduction to various traffic engineering basic characteristics which are useful in designing any corridor or passage with safety & reliability.
Traffic engineering deals with improving traffic flow and performance on road networks through systematic studies and engineering applications. It includes planning, design, regulation, and control of traffic. The objectives of traffic engineering are to achieve efficient and safe traffic flow with minimal delays and accidents. It covers various areas like traffic studies and analysis, planning, design, operation, safety, and administration. The overall goal is to facilitate convenient, rapid, and economic transportation of people and goods.
This document discusses traffic engineering and road user characteristics. It defines traffic engineering as dealing with planning and design of roads and highways, as well as traffic operation related to safe and efficient transportation. The key points covered include:
- The scope of traffic engineering includes traffic studies and analysis, traffic control and regulation, planning, geometric design, and administration.
- Traffic characteristics and road user characteristics are important to study, including physical, mental, and emotional traits of drivers.
- The functions of a traffic engineer include data collection and analysis, transportation planning, traffic design, and measures to operate and regulate traffic.
- Road user behavior is influenced by physical, psychological, and environmental factors. Reaction time and visual abilities
The document summarizes the results of a traffic survey conducted by a student group. It includes:
1) The objectives of studying vehicle composition, traffic stream properties, and directional distribution.
2) Findings from the survey such as the predominant vehicle type being personal vehicles and the directional distribution showing more traffic from Panthapath to Russell Square.
3) Limitations of the study related to resources and time constraints.
The document discusses a traffic volume study conducted at Russell Square in Dhaka. It defines key terms like average daily traffic (ADT) and level of service (LOS). Data was collected manually over three hours and analyzed to find a service flow rate of 1,131 passenger car units per hour, indicating an LOS of D. The average daily traffic was calculated as 16,080 passenger cars with an annual average of 22,432. Traffic movement was found to be nearly equal in both directions.
This document discusses traffic characteristics and engineering. It defines traffic engineering as dealing with planning and designing streets and highways for safe, efficient traffic flow. Road users and their physical, mental, psychological characteristics are examined, as well as vehicles' static properties like weight and dimensions, and dynamic properties like speed and braking. Traffic surveys study these characteristics to determine road geometry and controls. Perception, intellect, emotion and volition times that make up a driver's total reaction time are also outlined.
The document defines different types of traffic volumes used for transportation planning and design. Daily volumes like average annual daily traffic (AADT) are used to establish trends over time. Hourly volumes like the peak hour volume are most important for design and operational analysis. Within the peak hour, the peak 15-minute volume and peak hour factor (PHF) account for fluctuations in flow. Sub-hourly volumes below 15 minutes are also sometimes analyzed.
Chapter 6 Fundamentals of traffic flowFayaz Rashid
The document discusses fundamental principles of traffic flow, including the primary elements of traffic flow such as flow, density, speed, and headway. It describes flow-density relationships and the fundamental diagram of traffic flow. Mathematical models for describing macroscopic traffic flow relationships are presented, including the Greenshields model relating traffic density to speed. The primary elements, flow-density relationships, and Greenshields traffic flow model are summarized for understanding traffic flow characteristics.
this is a brief introduction to various traffic engineering basic characteristics which are useful in designing any corridor or passage with safety & reliability.
Traffic engineering deals with improving traffic flow and performance on road networks through systematic studies and engineering applications. It includes planning, design, regulation, and control of traffic. The objectives of traffic engineering are to achieve efficient and safe traffic flow with minimal delays and accidents. It covers various areas like traffic studies and analysis, planning, design, operation, safety, and administration. The overall goal is to facilitate convenient, rapid, and economic transportation of people and goods.
The document discusses the typical elements that make up the cross-section of a road, including the traveled way, roadway, median, shoulders, kerb, traffic barriers, drainage channels, and side slopes. It provides details on the purpose and design considerations for each element, such as recommended widths for different road types. The key factors in selecting appropriate cross-section elements are the expected traffic volumes and composition, as well as safety and physical constraints of the area where the road is located.
Traffic volume is a fundamental measure of traffic on a road system, measured as the number of vehicles crossing a section of road per unit time. It is used for various purposes like planning, design, and traffic management. There are manual and automatic methods to count traffic volume. Manual methods involve field observers counting and classifying vehicles in different time intervals, while automatic methods use technologies like pneumatic tubes buried in roads, inductive loops in pavements, and radar to detect vehicle presence and count traffic volume without human observers. The collected data is then analyzed to produce traffic flow maps, intersection diagrams, and trend charts to understand traffic patterns and inform transportation planning.
Traffic studies are carried out to analyze traffic characteristics and help decide geometric design and traffic control measures. The main traffic studies include traffic volume, speed, origin-destination, traffic flow characteristics, capacity, and accident studies. Traffic volume studies measure the number of vehicles on a road section over time and are used for planning, operations, and analysis. Speed studies measure the speeds of vehicles using methods like short-distance timing or radar guns.
This document contains information from a traffic study conducted at Shahid Tajuddin Ahmed Avenue in Dhaka, Bangladesh. A group of 6 students conducted manual traffic counts over two 15-minute periods in both directions at the location. They classified over 2000 vehicles and calculated passenger car equivalents, directional distribution, hourly flow rates, and average daily traffic. Their analysis found the directional split to be 54% from Shatrasta to the flyover and 46% from the flyover to Shatrasta. Peak hourly flows were around 2000 passenger car units in each direction. This traffic study provides data to understand volume, composition, and flow patterns at this location.
The document discusses various aspects of traffic regulation and control including driver controls, vehicle controls, traffic flow regulations, and general controls as per the Motor Vehicle Act. It describes different types of traffic control devices like signs, signals, markings, and islands. Specific topics covered include one-way streets, advantages and disadvantages of one-way systems, types of regulatory signs like stop, give way, prohibitory, no parking signs. Warning and informative signs are also explained.
Spot speed studies involve measuring the instantaneous speeds of vehicles at a point on the road. There are two main methods - measuring the time taken to travel a short distance or using a radar speed meter. Spot speeds are useful for traffic planning, road design, setting speed limits, and accident analysis. The radar method is efficient as it can instantly and automatically measure and record speeds accurately. Time-mean speed is the average of all instantaneous speeds measured, while space-mean speed represents the average speed of all vehicles traveling along a road section. Spot speed studies provide important input for various traffic engineering problems.
Traffic assignment models are used to estimate traffic flows on a transportation network based on origin-destination flows and the network's topology, link characteristics, and performance functions. Traffic is assigned to paths between origin-destination pairs based on travel time or impedance. Traffic assignment is a key part of travel demand forecasting and is used to predict future network flows and performance under different planning scenarios. Common traffic assignment methods include all-or-nothing assignment, user equilibrium assignment, and system optimum assignment.
Detailed description of Capacity and Level of service of Multi lane highways based on Highway Capacity Manual (HCM2010) along with one example for finding LOS of a highway
Traffic control devices include signs, signals, markings, and islands that regulate traffic flow and guide drivers. Signs communicate messages through regulatory signs that inform laws, warning signs that indicate hazards, and informative signs that direct routes. Signals use red, green, and yellow lights to alternately stop and direct traffic. Markings include painted lines and symbols on roads to guide drivers. Islands separate traffic directions and channels and provide pedestrian refuge. Together these devices aim to direct attention, allow time to respond, and ensure respect among all road users.
The document discusses various types of pavement failures including flexible and rigid pavement failures. For flexible pavements, failures include surface deformation (rutting, corrugation, shoving), cracking (fatigue, transverse, longitudinal), disintegration (potholes, patches), and surface defects (raveling, bleeding). Common causes are poor soil, inferior materials, improper geometry, overloading, and environmental factors. Maintenance techniques to address failures include bituminous surface treatments, asphalt overlays, slurry seals, and crack sealing. For rigid pavements, failures discussed are spalling at joints, scaling of cement concrete, and shrinkage cracks.
Urban transportation system - methods of route assignmentStudent
The document discusses various methods of route assignment in transportation systems, including:
- All-or-nothing assignment method, which assigns all trips to the minimum path but does not account for capacity.
- Direction curve method, which predicts route usage based on travel time or distance saved on a new facility.
- Capacity restraint assignment techniques, which iteratively assign trips accounting for changing travel times due to congestion.
- Multi-route assignment technique, which recognizes that not all travelers choose the absolute minimum path and distributes trips across multiple routes factoring attributes like travel time and cost.
Traffic engineering deals with applying scientific principles and techniques to facilitate the safe, efficient movement of people and goods. It aims to achieve free flow of traffic with minimal accidents. Key aspects studied include traffic characteristics, volumes, speeds, origins/destinations, flow, capacity, parking, and accidents. Data is collected through surveys and analysis informs planning, design, operation, and management of road infrastructure.
Capacity & level of service (transportation engineering)Civil Zone
This document discusses highway design speed and level of service. It defines design speed as the maximum safe speed for a road based on its geometric design features. Level of service is a qualitative measure of traffic conditions on a roadway, ranging from free-flowing traffic at LOS A to congested traffic at LOS F. The document provides examples of calculating level of service for a highway based on factors like lane width, access points, and traffic volume using methods from the Highway Capacity Manual. It shows how changes to the road design, such as adding lanes or widening lanes, can improve the level of service.
Rigid pavements are concrete slabs that distribute vehicle loads through beam action. They have high flexural strength and small deflections compared to flexible pavements. The presentation discusses the types of rigid pavements including jointed plain concrete, jointed reinforced concrete, and continuously reinforced concrete pavements. It also covers the design factors for rigid pavements such as traffic loading, subgrade strength, environmental conditions, and material properties. Rigid pavements are designed to last 30 years with minimal maintenance required over the design life.
Highway failure & their maintenance pptBeing Deepak
This document summarizes highway failure and maintenance. It discusses the main causes of highway failure such as rutting from temperature variations and heavy loads. The four major types of failure are cracking, surface deformation, disintegration, and surface defects. Highway maintenance aims to preserve and repair highways using materials like concrete, asphalt, and tar. It includes activities like sealing cracks, resurfacing, removing snow, and bridge upkeep to provide safety and efficient travel. Proper maintenance helps strengthen roads and reduce maintenance costs over time.
Transportation and highway engineering part 1 GEOMIND
The document provides an introduction to highway engineering. It discusses the objectives of understanding transportation engineering and the road development process. Transportation engineering is defined as applying technology and science to safely and efficiently move people and goods via various modes of transportation. The scope of highway engineering includes development and planning, design, traffic performance, materials and construction, economics and administration. Key aspects covered are historical road development in India, the Jayakar Committee report, and the transportation system as diverse, changing, and requiring an understanding of engineering, economics and other disciplines.
This document provides an overview of transportation engineering, including the objectives of the course and various modes of transportation. It describes the main modes as road, rail, maritime, air, and pipelines. It also defines a transportation system as consisting of fixed facilities, flow entities, and a control system. Transportation planning is discussed as a process involving survey, analysis, forecasting, evaluation, adoption, implementation and ongoing studies to develop an efficient system.
The document discusses the typical elements that make up the cross-section of a road, including the traveled way, roadway, median, shoulders, kerb, traffic barriers, drainage channels, and side slopes. It provides details on the purpose and design considerations for each element, such as recommended widths for different road types. The key factors in selecting appropriate cross-section elements are the expected traffic volumes and composition, as well as safety and physical constraints of the area where the road is located.
Traffic volume is a fundamental measure of traffic on a road system, measured as the number of vehicles crossing a section of road per unit time. It is used for various purposes like planning, design, and traffic management. There are manual and automatic methods to count traffic volume. Manual methods involve field observers counting and classifying vehicles in different time intervals, while automatic methods use technologies like pneumatic tubes buried in roads, inductive loops in pavements, and radar to detect vehicle presence and count traffic volume without human observers. The collected data is then analyzed to produce traffic flow maps, intersection diagrams, and trend charts to understand traffic patterns and inform transportation planning.
Traffic studies are carried out to analyze traffic characteristics and help decide geometric design and traffic control measures. The main traffic studies include traffic volume, speed, origin-destination, traffic flow characteristics, capacity, and accident studies. Traffic volume studies measure the number of vehicles on a road section over time and are used for planning, operations, and analysis. Speed studies measure the speeds of vehicles using methods like short-distance timing or radar guns.
This document contains information from a traffic study conducted at Shahid Tajuddin Ahmed Avenue in Dhaka, Bangladesh. A group of 6 students conducted manual traffic counts over two 15-minute periods in both directions at the location. They classified over 2000 vehicles and calculated passenger car equivalents, directional distribution, hourly flow rates, and average daily traffic. Their analysis found the directional split to be 54% from Shatrasta to the flyover and 46% from the flyover to Shatrasta. Peak hourly flows were around 2000 passenger car units in each direction. This traffic study provides data to understand volume, composition, and flow patterns at this location.
The document discusses various aspects of traffic regulation and control including driver controls, vehicle controls, traffic flow regulations, and general controls as per the Motor Vehicle Act. It describes different types of traffic control devices like signs, signals, markings, and islands. Specific topics covered include one-way streets, advantages and disadvantages of one-way systems, types of regulatory signs like stop, give way, prohibitory, no parking signs. Warning and informative signs are also explained.
Spot speed studies involve measuring the instantaneous speeds of vehicles at a point on the road. There are two main methods - measuring the time taken to travel a short distance or using a radar speed meter. Spot speeds are useful for traffic planning, road design, setting speed limits, and accident analysis. The radar method is efficient as it can instantly and automatically measure and record speeds accurately. Time-mean speed is the average of all instantaneous speeds measured, while space-mean speed represents the average speed of all vehicles traveling along a road section. Spot speed studies provide important input for various traffic engineering problems.
Traffic assignment models are used to estimate traffic flows on a transportation network based on origin-destination flows and the network's topology, link characteristics, and performance functions. Traffic is assigned to paths between origin-destination pairs based on travel time or impedance. Traffic assignment is a key part of travel demand forecasting and is used to predict future network flows and performance under different planning scenarios. Common traffic assignment methods include all-or-nothing assignment, user equilibrium assignment, and system optimum assignment.
Detailed description of Capacity and Level of service of Multi lane highways based on Highway Capacity Manual (HCM2010) along with one example for finding LOS of a highway
Traffic control devices include signs, signals, markings, and islands that regulate traffic flow and guide drivers. Signs communicate messages through regulatory signs that inform laws, warning signs that indicate hazards, and informative signs that direct routes. Signals use red, green, and yellow lights to alternately stop and direct traffic. Markings include painted lines and symbols on roads to guide drivers. Islands separate traffic directions and channels and provide pedestrian refuge. Together these devices aim to direct attention, allow time to respond, and ensure respect among all road users.
The document discusses various types of pavement failures including flexible and rigid pavement failures. For flexible pavements, failures include surface deformation (rutting, corrugation, shoving), cracking (fatigue, transverse, longitudinal), disintegration (potholes, patches), and surface defects (raveling, bleeding). Common causes are poor soil, inferior materials, improper geometry, overloading, and environmental factors. Maintenance techniques to address failures include bituminous surface treatments, asphalt overlays, slurry seals, and crack sealing. For rigid pavements, failures discussed are spalling at joints, scaling of cement concrete, and shrinkage cracks.
Urban transportation system - methods of route assignmentStudent
The document discusses various methods of route assignment in transportation systems, including:
- All-or-nothing assignment method, which assigns all trips to the minimum path but does not account for capacity.
- Direction curve method, which predicts route usage based on travel time or distance saved on a new facility.
- Capacity restraint assignment techniques, which iteratively assign trips accounting for changing travel times due to congestion.
- Multi-route assignment technique, which recognizes that not all travelers choose the absolute minimum path and distributes trips across multiple routes factoring attributes like travel time and cost.
Traffic engineering deals with applying scientific principles and techniques to facilitate the safe, efficient movement of people and goods. It aims to achieve free flow of traffic with minimal accidents. Key aspects studied include traffic characteristics, volumes, speeds, origins/destinations, flow, capacity, parking, and accidents. Data is collected through surveys and analysis informs planning, design, operation, and management of road infrastructure.
Capacity & level of service (transportation engineering)Civil Zone
This document discusses highway design speed and level of service. It defines design speed as the maximum safe speed for a road based on its geometric design features. Level of service is a qualitative measure of traffic conditions on a roadway, ranging from free-flowing traffic at LOS A to congested traffic at LOS F. The document provides examples of calculating level of service for a highway based on factors like lane width, access points, and traffic volume using methods from the Highway Capacity Manual. It shows how changes to the road design, such as adding lanes or widening lanes, can improve the level of service.
Rigid pavements are concrete slabs that distribute vehicle loads through beam action. They have high flexural strength and small deflections compared to flexible pavements. The presentation discusses the types of rigid pavements including jointed plain concrete, jointed reinforced concrete, and continuously reinforced concrete pavements. It also covers the design factors for rigid pavements such as traffic loading, subgrade strength, environmental conditions, and material properties. Rigid pavements are designed to last 30 years with minimal maintenance required over the design life.
Highway failure & their maintenance pptBeing Deepak
This document summarizes highway failure and maintenance. It discusses the main causes of highway failure such as rutting from temperature variations and heavy loads. The four major types of failure are cracking, surface deformation, disintegration, and surface defects. Highway maintenance aims to preserve and repair highways using materials like concrete, asphalt, and tar. It includes activities like sealing cracks, resurfacing, removing snow, and bridge upkeep to provide safety and efficient travel. Proper maintenance helps strengthen roads and reduce maintenance costs over time.
Transportation and highway engineering part 1 GEOMIND
The document provides an introduction to highway engineering. It discusses the objectives of understanding transportation engineering and the road development process. Transportation engineering is defined as applying technology and science to safely and efficiently move people and goods via various modes of transportation. The scope of highway engineering includes development and planning, design, traffic performance, materials and construction, economics and administration. Key aspects covered are historical road development in India, the Jayakar Committee report, and the transportation system as diverse, changing, and requiring an understanding of engineering, economics and other disciplines.
This document provides an overview of transportation engineering, including the objectives of the course and various modes of transportation. It describes the main modes as road, rail, maritime, air, and pipelines. It also defines a transportation system as consisting of fixed facilities, flow entities, and a control system. Transportation planning is discussed as a process involving survey, analysis, forecasting, evaluation, adoption, implementation and ongoing studies to develop an efficient system.
This document provides an overview of a course on highway planning and design. It discusses the course learning outcomes, which are to assess highway routes for complex situations, design sustainable pavement structures, and justify analysis and design decisions. It also summarizes key concepts in transportation planning, including defining transportation and its components, and outlining the transportation planning process.
This document discusses system concepts in transportation. It covers system concepts for passengers, goods/freight, and intermodal transport. For passengers, it discusses requirements like terminals and amenities, as well as concepts like park and ride and kiss and ride. For goods, it focuses on minimizing loading/unloading time and concepts like RORO and LASH. Intermodal transport combines multiple modes without handling freight. Other sections discuss transport and logistics, just-in-time concepts, third party logistics, and the relationship between transport and tourism.
This document provides an overview of transportation engineering. It defines transportation engineering as the application of technology and scientific principles to planning, designing, operating, and managing facilities for transporting people and goods. It discusses the importance of transportation for a country's development and economy. It also outlines the major modes of transportation, including roads, railways, waterways, and airways, describing their key characteristics. The document focuses on the characteristics of road transportation and its importance as the most accessible mode. It concludes by discussing factors that influence the choice of transportation mode.
This document summarizes a dissertation on multi-modal transportation hubs. The dissertation aims to study the need for and circulation involved in multi-modal transportation. The objectives are to study transitional areas, requirements, and circulation. The scope is on uses and passenger movement patterns. Due to time constraints, some aspects could not be studied in depth. Case studies of London, Hong Kong and Singapore multi-modal hubs are provided. Conventional transportation planning is compared to multi-modal planning, which considers connections between modes. Passenger requirements like transfer times and accessibility are also discussed.
Transportation and Traffic Engineering Dr. Sheriff El-Badawy ( Introduction )Hossam Shafiq I
This document appears to be lecture slides for a transportation and traffic engineering course. It includes definitions of transportation engineering and traffic engineering. It outlines the course contents which cover topics like transportation planning, traffic flow characteristics, highway geometric design, and traffic control devices. It also defines key concepts like trips, transportation systems, land use and its relationship to transportation, and highway functional classification. The overall aim of the course is to introduce students to the fundamentals and principles of transportation and traffic engineering.
Transport involves moving people, goods, or animals from one location to another. There are various modes of transportation including air, land, water, and pipeline. Each mode has distinct characteristics like speed, cost, and cargo capacity. Land transportation includes road, rail, and off-road transport. Transport infrastructure enables the movement of people and goods and includes roads, railways, airways, waterways, canals, terminals, and facilities like ports, stations, and warehouses. The efficient management of transportation and supply chains relies on optimizing resources, managing costs and finances, adopting technology, and accounting for environmental factors.
The document provides an outline for the course Transportation Engineering - I. It covers various topics related to highway planning, design, traffic engineering, and railway engineering. These include highway classification, geometric design elements, drainage, intersections, traffic surveys, road signs and signals, and railway track design. It also defines key terms related to transportation planning and engineering such as location controls, mobility vs accessibility, and urban road classification. Recommended textbooks are provided at the end.
Intelligent Transportation Systems (ITS) is the application of computer, electronics, and communication technologies and management strategies in an integrated manner to provide traveler information to increase the safety and efficiency of the road transportation systems.
The document outlines the details of Chennai Metro Phase II project including the team members, purpose, scope, beneficiaries, motivation and roadmap. The key points are:
1) The project aims to provide a fast, efficient and economical public transport system to address the growing traffic in Chennai.
2) The scope of work includes civil works, station design, train operations planning, power supply, signaling and cost estimation.
3) Mass transit systems like Metro benefit the public by providing safe, quick transportation and reducing congestion and pollution in the city.
This presentation provides an overview of road networks. It defines a road network as a system of interconnected paved roads designed to carry vehicles and link urban and rural areas. The presentation discusses the components of a road network including intersections, urban and rural roads, motorways, and footpaths. It also covers the design, characteristics, hierarchy, assessment and analysis of road networks. Intelligent transport systems are introduced as techniques to contribute to safer and more efficient travel, including traffic control and traveler information methods.
The document discusses features of transportation in logistics. It describes how transportation plays a vital role in logistics by connecting different parts of the supply chain and enabling the movement of goods. Some key features of transportation discussed include optimization of routes and carrier selection, integration with warehouse management systems, and performance tracking capabilities. Transportation management systems provide benefits like increased customer service, warehouse efficiency, and inventory reductions. Overall, the document outlines the significance of transportation in logistics operations.
The document outlines the syllabus for a course on highway and railway engineering. It covers topics such as highway planning and alignment, geometric design of highways, pavement design, basics of railway engineering, and advanced railway topics. The course examines factors in transportation development and methods for designing efficient road and rail infrastructure networks.
Here are potential answers to the assignment questions:
1. Explain different modes of transportation with their benefits and limitations:
The main modes of transportation are road, rail, water, air and pipeline. Each has its own benefits and limitations in terms of cost, speed, capacity, route limitations etc. For example, road transportation provides door-to-door delivery but has higher costs compared to rail. Water transportation has the lowest cost per ton-km but is slower and limited to routes.
2. What transport decisions should a manager take into consideration while selecting the transportation mode?
A manager should consider factors like nature of goods, urgency of delivery, cost constraints, availability of modes, transportation infrastructure etc. Key decisions include
Transportation management involves organizing the movement of people and goods. It includes four key components: the way or path of travel, terminals for access, vehicles for carrying people/goods, and motive power. As part of the tourist product, transportation provides access to destinations and local movement, and can sometimes be an attraction itself like cruises. When selecting transportation modes, considerations include responsiveness, reliability, and relationships. Transportation adds value by delivering people/goods where and when needed.
The Texas A&M Transportation Institute (TTI) was asked by the Texas Department of Transportation (TxDOT) to assist in the application and refinement of prior research to accomplish some key goals during the reconstruction of the I-35 corridor from Hillsboro to Salado (90 miles total). Currently, TxDOT is conducting 10 construction projects along this corridor. More than 30 million drivers, including travelers, shippers and intercity commuters, use the corridor each year.
Traffic engineering deals with planning, designing, and operating roads and their relationships to other transportation modes. The primary goal is safety, with other objectives including speed, comfort, convenience, economy, and environmental compatibility. Traffic engineering studies collect data through inventories, administrative records, and dynamic studies of factors like speeds, volumes, travel times, parking, and crashes. Volume studies include average annual daily traffic, average daily traffic, and peak hour volumes to analyze highway usage. Travel time studies determine the time required to travel between points and identify delay locations and causes.
This document discusses the geometric design of highways. It covers key elements such as cross sections, horizontal and vertical curves, sight distances, and design control criteria. The objectives of geometric design are to incorporate physical features safely and efficiently while promoting environmental and human factors. Design is based on road classification, design speed, design vehicle, traffic volumes, and safety considerations. Cross sections specify elements like lanes, shoulders, medians and right of way widths. Proper geometric design can decrease construction and maintenance costs while ensuring consistent traffic flow.
The document provides information about the Eglinton Crosstown LRT project in Toronto. It discusses the need for improved transit due to traffic congestion, outlines Metrolinx's mandate to plan and build transit projects, and provides details about the construction of the Eglinton Crosstown line. Specifically, it will be a 19km light rail line running mostly underground with 25 stations. Construction is underway using different methods and will continue through 2019, with impacts to traffic and pedestrians along Eglinton Avenue.
Internal Control Internal Checking Internal Auditing - Auditing By LATiFHRWLatif Hyder Wadho
This document discusses internal control, internal check, and internal audit. It defines these terms and outlines their objectives and characteristics. Internal control involves plans and measures to safeguard a business's assets. Internal check involves segregating duties among staff to check each other's work and prevent fraud and errors. Internal audit is an independent review of a company's operations, policies, controls, and accounting processes to evaluate effectiveness and risks. The document provides details on how these tools help management and auditors ensure accuracy, accountability, and effective decision making.
This document discusses demand and supply in economics. It defines demand as the quantity of goods consumers are willing and able to buy at a given price. The quantity demanded changes inversely with price, as shown by the demand curve. Supply is defined as the quantity of a good sellers are willing and able to sell. According to the law of supply, the quantity supplied increases with price. The document lists factors that influence both demand and supply such as income, prices, and technology.
The document provides information about lectures on surveying topics including:
- Classification of theodolites as transit, non-transit, vernier, and micrometer theodolites.
- Uses of theodolites for measuring horizontal and vertical angles, locating points, and other surveying tasks.
- Terms used in manipulating a transit vernier theodolite such as centering, transiting, swinging the telescope, and changing face.
- Bearings and the rules for converting whole circle bearings to quadrantal/reduced bearings.
- Definitions of open and closed traverses and the formula to check the interior angles of a closed traverse.
- An example problem on calculating
The document discusses Pakistan's energy crisis, including its causes and recommendations. It notes that Pakistan faces a shortage of 4,000-9,000 MW of electricity per day due to growing demand outpacing available generation. Recommendations include increasing independent power production and reactivating closed plants in the short term, while long term plans involve developing coal power, securing agreements for sustainable energy imports, and exploring more oil, gas, and coal reserves. The study concludes by recommending the government overhaul infrastructure to utilize more renewable energy and coal reserves.
The document outlines the procedure, syllabus, and requirements for admission to the Combined Competitive Examination held by the Sindh Public Service Commission. It provides details on eligibility criteria, application process, examination structure and syllabus. Key points include: the examination may be held in Karachi, Hyderabad, Sukkur or Larkana; the written examination will include compulsory and optional subjects with a total of 900 marks; candidates must submit documents including degree certificates and domicile/residence proofs along with the application.
The document contains three words: 2013, PCS past papers, and LATIF HYDER WADHO. It appears to reference past exam papers from 2013 for the Pakistan Civil Service exam, possibly authored by or pertaining to an individual named Latif Hyder Wadho.
The document appears to be a screening test paper from 2013 for an individual named Latif Hyder Wadho. It does not provide much other contextual information within its brief text.
This document outlines an engineering drawing course, including:
- The course covers topics such as basic concepts of engineering drawing, instruments and their uses, orthographic drawings, isometric views, sectional views, and auxiliary views.
- It lists reference textbooks for the course and provides a class schedule covering topics week by week.
- Notes specify requirements for attendance, necessary instruments for classes, and exams that will be used to calculate final grades.
- Additional sections cover graphics language, traditional drawing tools, projection methods, drawing standards, and line conventions. Diagrams and examples are provided to illustrate key concepts.
This document discusses the history and spread of the English language globally. It describes how English originated in Britain but was exported worldwide through colonization. Varieties of English developed in colonies like America, Australia, and Africa. While British English was once the predominant standard, American English has increasingly influenced other varieties due to U.S. economic and cultural power post-World War 2. Today, English serves as a key international language for trade, education, and diplomacy due to Britain and America's historical political-economic dominance as global superpowers over the 19th-20th centuries.
This document provides information about bricks, including their types, characteristics, classification based on quality, and manufacturing processes. It discusses the different classes of bricks from first to fourth class based on their quality. It also outlines the key properties that good bricks should have, such as uniform color, standard size and shape, fine texture, hardness, strength, and resistance to water absorption and efflorescence. The document explains the traditional and modern methods used to manufacture bricks, including molding and firing processes.
Geotechnical engineering is a branch of civil engineering that applies soil mechanics, rock mechanics, and groundwater conditions to design foundations, retaining structures, earth structures, and environmental containment systems. Geological engineers use principles of earth sciences and geotechnical engineering to solve problems involving soil, rock, and groundwater, and to design underground structures. They often work with other professionals on major projects involving site selection, natural hazards, foundations, groundwater, slopes, dams, and environmental remediation.
Saw-tooth bits have a series of teeth on the cutting edge that are tipped with hard metals like tungsten carbide for wear resistance. They are less expensive but usually only used for soft soils and rocks. Rotary drilling uses a rotating bit and downward force to drill holes in soil or rock. Intact samples can be obtained using core barrels while drilling, and disturbed samples of cuttings are collected from the flushed material returning up the hole.
A group of 16 square piles extends 12 m into stiff clay soil, underlain by rock at 24 m depth. Pile dimensions are 0.3 m x 0.3 m. Undrained shear strength of clay increases linearly from 50 kPa at surface to 150 kPa at rock. Factor of safety for group capacity is 2.5. Determine group capacity and individual pile capacity.
The group capacity is calculated to be 1600 kN. The individual pile capacity is determined to be 100 kN. The factor of safety of 2.5 is then applied to determine the safe load capacity.
- There are four main methods to measure the load carrying capacity of piles: static methods, dynamic formulas, in-situ penetration tests, and pile load tests.
- The ultimate load capacity (Qu) of an individual pile or pile group equals the sum of the point resistance (Qp) at the pile tip and the shaft resistance (Qs) developed along the pile shaft through friction between the soil and pile.
- Meyerhof's method is commonly used to calculate Qp in sand based on the effective vertical pressure at the pile tip multiplied by the bearing capacity factor Nq.
The document provides information about a 21 meter long prestressed concrete pile driven into sand. The pile has an allowable working load of 502 kN, with an octagonal cross-section of 0.356 meters diameter and area of 0.1045 m^2. Skin resistance supports 350 kN of the load and point bearing the rest. The document requests calculating the elastic settlement of the pile given its properties, the load distribution, and soil parameters.
A plate load test involves applying incremental loads to a bearing plate placed on the ground surface and measuring the resulting settlements. The test is used to estimate the settlement of a footing under working loads. A seating load is first applied and removed, then higher loads are placed and settlements are recorded until the rate of settlement decreases. Load-settlement curves are plotted from the results. The test gives the immediate settlement but not long-term consolidation settlement, so it is not very useful for predicting behavior in clay soils. The test also may not be representative if the soil is not homogeneous to a depth of 1.5-2 times the prototype footing width.
The document discusses various methods and procedures for conducting subsurface exploration projects. It covers topics such as coring of rock, observation of water levels, collecting groundwater samples, bore logs, soil sampling techniques, and trial pits and trenches. The key points are that subsurface exploration involves drilling boreholes, measuring strata and water levels, obtaining soil and rock samples, recording bore logs, and investigating shallow depths using excavated pits and trenches. Proper exploration is important for understanding ground conditions and aid engineering design and construction.
The document discusses subsurface exploration, which involves determining the soil layers and properties beneath a proposed structure. It describes the various phases of a soil investigation: collecting existing information, conducting site visits, preliminary exploration including some boreholes, detailed exploration with more boreholes and laboratory/in-situ testing, and reporting findings. Guidelines are provided for borehole depth, spacing, and number based on factors like structure type and loads, soil variability, and cost. Common subsurface exploration methods include test pits, hand augers, mechanical augers, shell and auger borings, percussion borings, wash borings, rotary borings, and diamond core drilling.
This document outlines the syllabus for a foundation engineering course. It covers topics such as soil exploration, shallow foundations, deep foundations, earthen dams, and foundations on difficult soils. The course will explore soil testing methods, bearing capacity calculations, pile load capacity, and dam design considerations. References textbooks on geotechnical engineering and foundation design are also listed.
KuberTENes Birthday Bash Guadalajara - K8sGPT first impressionsVictor Morales
K8sGPT is a tool that analyzes and diagnoses Kubernetes clusters. This presentation was used to share the requirements and dependencies to deploy K8sGPT in a local environment.
Literature Review Basics and Understanding Reference Management.pptxDr Ramhari Poudyal
Three-day training on academic research focuses on analytical tools at United Technical College, supported by the University Grant Commission, Nepal. 24-26 May 2024
A SYSTEMATIC RISK ASSESSMENT APPROACH FOR SECURING THE SMART IRRIGATION SYSTEMSIJNSA Journal
The smart irrigation system represents an innovative approach to optimize water usage in agricultural and landscaping practices. The integration of cutting-edge technologies, including sensors, actuators, and data analysis, empowers this system to provide accurate monitoring and control of irrigation processes by leveraging real-time environmental conditions. The main objective of a smart irrigation system is to optimize water efficiency, minimize expenses, and foster the adoption of sustainable water management methods. This paper conducts a systematic risk assessment by exploring the key components/assets and their functionalities in the smart irrigation system. The crucial role of sensors in gathering data on soil moisture, weather patterns, and plant well-being is emphasized in this system. These sensors enable intelligent decision-making in irrigation scheduling and water distribution, leading to enhanced water efficiency and sustainable water management practices. Actuators enable automated control of irrigation devices, ensuring precise and targeted water delivery to plants. Additionally, the paper addresses the potential threat and vulnerabilities associated with smart irrigation systems. It discusses limitations of the system, such as power constraints and computational capabilities, and calculates the potential security risks. The paper suggests possible risk treatment methods for effective secure system operation. In conclusion, the paper emphasizes the significant benefits of implementing smart irrigation systems, including improved water conservation, increased crop yield, and reduced environmental impact. Additionally, based on the security analysis conducted, the paper recommends the implementation of countermeasures and security approaches to address vulnerabilities and ensure the integrity and reliability of the system. By incorporating these measures, smart irrigation technology can revolutionize water management practices in agriculture, promoting sustainability, resource efficiency, and safeguarding against potential security threats.
ACEP Magazine edition 4th launched on 05.06.2024Rahul
This document provides information about the third edition of the magazine "Sthapatya" published by the Association of Civil Engineers (Practicing) Aurangabad. It includes messages from current and past presidents of ACEP, memories and photos from past ACEP events, information on life time achievement awards given by ACEP, and a technical article on concrete maintenance, repairs and strengthening. The document highlights activities of ACEP and provides a technical educational article for members.
Low power architecture of logic gates using adiabatic techniquesnooriasukmaningtyas
The growing significance of portable systems to limit power consumption in ultra-large-scale-integration chips of very high density, has recently led to rapid and inventive progresses in low-power design. The most effective technique is adiabatic logic circuit design in energy-efficient hardware. This paper presents two adiabatic approaches for the design of low power circuits, modified positive feedback adiabatic logic (modified PFAL) and the other is direct current diode based positive feedback adiabatic logic (DC-DB PFAL). Logic gates are the preliminary components in any digital circuit design. By improving the performance of basic gates, one can improvise the whole system performance. In this paper proposed circuit design of the low power architecture of OR/NOR, AND/NAND, and XOR/XNOR gates are presented using the said approaches and their results are analyzed for powerdissipation, delay, power-delay-product and rise time and compared with the other adiabatic techniques along with the conventional complementary metal oxide semiconductor (CMOS) designs reported in the literature. It has been found that the designs with DC-DB PFAL technique outperform with the percentage improvement of 65% for NOR gate and 7% for NAND gate and 34% for XNOR gate over the modified PFAL techniques at 10 MHz respectively.
We have compiled the most important slides from each speaker's presentation. This year’s compilation, available for free, captures the key insights and contributions shared during the DfMAy 2024 conference.
Understanding Inductive Bias in Machine LearningSUTEJAS
This presentation explores the concept of inductive bias in machine learning. It explains how algorithms come with built-in assumptions and preferences that guide the learning process. You'll learn about the different types of inductive bias and how they can impact the performance and generalizability of machine learning models.
The presentation also covers the positive and negative aspects of inductive bias, along with strategies for mitigating potential drawbacks. We'll explore examples of how bias manifests in algorithms like neural networks and decision trees.
By understanding inductive bias, you can gain valuable insights into how machine learning models work and make informed decisions when building and deploying them.
Advanced control scheme of doubly fed induction generator for wind turbine us...IJECEIAES
This paper describes a speed control device for generating electrical energy on an electricity network based on the doubly fed induction generator (DFIG) used for wind power conversion systems. At first, a double-fed induction generator model was constructed. A control law is formulated to govern the flow of energy between the stator of a DFIG and the energy network using three types of controllers: proportional integral (PI), sliding mode controller (SMC) and second order sliding mode controller (SOSMC). Their different results in terms of power reference tracking, reaction to unexpected speed fluctuations, sensitivity to perturbations, and resilience against machine parameter alterations are compared. MATLAB/Simulink was used to conduct the simulations for the preceding study. Multiple simulations have shown very satisfying results, and the investigations demonstrate the efficacy and power-enhancing capabilities of the suggested control system.
DEEP LEARNING FOR SMART GRID INTRUSION DETECTION: A HYBRID CNN-LSTM-BASED MODELgerogepatton
As digital technology becomes more deeply embedded in power systems, protecting the communication
networks of Smart Grids (SG) has emerged as a critical concern. Distributed Network Protocol 3 (DNP3)
represents a multi-tiered application layer protocol extensively utilized in Supervisory Control and Data
Acquisition (SCADA)-based smart grids to facilitate real-time data gathering and control functionalities.
Robust Intrusion Detection Systems (IDS) are necessary for early threat detection and mitigation because
of the interconnection of these networks, which makes them vulnerable to a variety of cyberattacks. To
solve this issue, this paper develops a hybrid Deep Learning (DL) model specifically designed for intrusion
detection in smart grids. The proposed approach is a combination of the Convolutional Neural Network
(CNN) and the Long-Short-Term Memory algorithms (LSTM). We employed a recent intrusion detection
dataset (DNP3), which focuses on unauthorized commands and Denial of Service (DoS) cyberattacks, to
train and test our model. The results of our experiments show that our CNN-LSTM method is much better
at finding smart grid intrusions than other deep learning algorithms used for classification. In addition,
our proposed approach improves accuracy, precision, recall, and F1 score, achieving a high detection
accuracy rate of 99.50%.
Presentation of IEEE Slovenia CIS (Computational Intelligence Society) Chapte...University of Maribor
Slides from talk presenting:
Aleš Zamuda: Presentation of IEEE Slovenia CIS (Computational Intelligence Society) Chapter and Networking.
Presentation at IcETRAN 2024 session:
"Inter-Society Networking Panel GRSS/MTT-S/CIS
Panel Session: Promoting Connection and Cooperation"
IEEE Slovenia GRSS
IEEE Serbia and Montenegro MTT-S
IEEE Slovenia CIS
11TH INTERNATIONAL CONFERENCE ON ELECTRICAL, ELECTRONIC AND COMPUTING ENGINEERING
3-6 June 2024, Niš, Serbia
2. OverviewOverview
• This course aims at providing the
student an introduction to
Transportation Engineering. The
course is organized under five
modules. These are:
2
3. • Introduction to Transporation
Systems Engineering
• Transportation Planning
• Geometric Design
• Pavement Design
• Traffic Engineering
3
4. ObjectivesObjectives
• Introduction to Transportation
Systems Engineering
• Objective of this module is to give an overview of
the transportaion engineering.
• The focus will be to present a systems approach
where the interaction of humans and the vehicles
and their impact on the society and
transportation.
4
5. ObjectivesObjectives
• Transportation Planning plays an
important role in a region's strategy
to improve the performance of the
transportation system.
• Objective of this module is to
describe the basic characteristics of
transportation planning and of the
models used by transportation
planners.
5
6. ObjectivesObjectives
• Geometric Design of highways deals with the
dimensions and layout visible features such as,
alignment, sight distances and intersections.
• Objective of this module is to describe highway
design objectives, constraints and controlling
factors, also to describe the criteria, standards
and engineering procedures used to design
principal elements of the highway alignment, and
highway cross sections.
6
7. ObjectivesObjectives
• Pavement Design based on empirical and
mechanistic relations between materials,
geometry and performance.
• Objective of this module is to understand the
process of collecting information necessary for
successful design of flexible and rigid pavements,
including traffic data, material properties and
other environmental factors.
7
8. ObjectivesObjectives
• Traffic Engineering includes traffic signs,
markings, traffic signals, islands etc.
• Objective of this module is to understand
the basic parameter of traffic engineering
and the methods to estimate those
parameters.
• It examines ways to promote operational
efficiency and safety through the use of
traffic control devices.
8
9. 9
S. # TOPICS
Lecture
Required
01 Transportation system: Introduction 1
02 Evolution of Transportation /Highway Development in Pakistan 1
03 Highway planning 1
04 Geometric design: Introduction/ Design controls 1
05 Design vehicle 1
06 Functional classification of roads and Design speed 1
07 Design Driver 1
08 Design Volume 1
09 Sight Distances 3
10
Cross section elements (with of travel lane, shoulders, medians
……)
2
MEHRAN UNIUVERSITY OF ENGINEERING AND TECHNOLOGY
RM-001/00QSP-004 Dec.01.2001
TENTATIVE TEACHING PLAN
DEPARTMENT/INSTITUTE/DIRECTORATE: CIVIL ENGINEERING
Name of Teacher: Prof. Dr. Abdul Sami Qureshi
Subject: Highway & Traffic Engineering Batch: 08CE- Year: Final Term: 1st
Term Starting Date: 03-01-2011 Term Suspension Date: 24-04-2011
11. REFERENCESREFERENCES
1. HIGHWAY ENGINEERINGPAUL
H. WRIGHT/ KAREN K. DIXON
1. TRANSPORTATION ENGINEERING
C. JOTIN KHISTY-B. KENT LALL
1. HIGHWAY ENGINEERING
J. KHANNA
1. THE HAND BOOK OF HIGHWAY ENGINEERING
T. F. FWA
1. http://nptel.iitm.ac.in/
2. http://ocw.mit.edu/OcwWeb/web/home/home/in
dex.htm
3. HIGHWAY CAPACITY MANUAL
11
14. Transportation SystemTransportation System
Definition of Transportation Modes
• A transportation system is an
infrastructure that serves to move people
and goods efficiently.
• Efficient = safe, rapid, comfortable,
convenient, economical, environmentally
compatible.
15. Transportation SystemTransportation System
Major transportation subsystems
• Land transportation: highway, rail
• Air transportation: domestic,
international
• Water transportation: inland, coastal,
ocean
• Pipelines: oil, gas, other
17. MAJOR INTERACTING COMPONENTSMAJOR INTERACTING COMPONENTS
InfrastructureInfrastructure
Vehicle / ServiceVehicle / Service
Users /Users /
SubstanceSubstance
18. Users / ContentUsers / Content
• People → Passenger Transportation
• Goods → Freight Transportation
Shareoftotalpassengersor
tons-km
Distance
Passengers
Commuting
Shopping
Recreation
Business
Tourism
Migration
Waste disposal
Local distribution
Trade
Energy & Raw Materials
Freight
Source: Dr. Jean-Paul Rodrigue, Dept. of Economics & Geography, Hofstra University.
19. Users / substanceUsers / substance
Passengers Freight
Board, get off and transfer
without assistance
Must be loaded, unloaded
and transferred
Process information and
act on it without assistance
The information must be
processed through logistics
managers
Make choices between
means of transport often
irrationally
Logistics managers make
choices between means of
transport rationally
Source: Dr. Jean-Paul Rodrigue, Dept. of Economics & Geography, Hofstra University.
37. Evolution of TransportationEvolution of Transportation
2000
Maritime Road Rail Air
180019001950
Docks
Locks
RailsOmnibus
Steam engine
Electric motor
Balloons
Dirigibles
Iron
hulls
Internal combustion engine
Metro
TramwayAutomobileLiners
Bicycles
PlanesTrucks
Buses
Electric
car
Hydrogen
car
Airfoils
Super
tankers
TGV
Maglev
Jet engine
Jet Plane
Container
ships
Helicopters
Bulk ships
Highways
Jumbo Jet
38. Evolution of TransportationEvolution of Transportation
1500-1840 Average speed of wagon and sail
ships: 16 km/hr
1850-1930 Average speed of trains: 100 km/hr.
Average speed of steamships: 25 km/hr
1950 Average speed of airplanes: 480-640 km/hr
1970 Average speed of jet planes: 800-1120 km/hr
1990 Numeric transmission: instantaneous
Source: Dr. Jean-Paul Rodrigue, Dept. of Economics & Geography, Hofstra University.
39. Evolution of TransportationEvolution of Transportation
100
500
1000
1800 1900 20001850 1950
50
250
750
Stage Coach
Rail
Automobile
HST
Propeller Plane
Jet Plane
Liner
Clipper Ship Containership
Road
Maritime
Rail
Air
Km
/hr
40. Evolution of TransportationEvolution of Transportation
• The TGV (French: Train à Grande Vitesse, meaning high-speed train) is
France's high-speed rail service
• A TGV service previously held the record for the fastest scheduled rail
journey with a start to stop average speed of 279.4 km/h (173.6 mph),[2][3]
which was surpassed by the Chinese CRH service Harmony express on the
Wuhan–Guangzhou High-Speed Railway in 2009.
• Maglev (magnetic levitation), is a system of transportation that suspends,
guides and propels vehicles, predominantly trains, using magnetic
levitation from a very large number of magnets for lift and propulsion.
• A hydrogen vehicle is an alternative fuel vehicle that uses hydrogen as
its onboard fuel for motive power
• Buses, trains, motorcycles,, ships, airplanes, submarines, and rockets can
already run on hydrogen, in various forms.The current land speed record
for a hydrogen-powered vehicle is 286.476 mph (461.038 km/h)
40
41. 41
• Now a days Supertankers has a length overall of 380.0 metres
(1,246.7 ft) and a cargo capacity of 3,166,353 barrels
(503,409,900 l).
43. 43
A jet aircraft is an aircraft propelled by jet engines. Jet aircraft
generally fly much faster than propeller-powered aircraft and at
higher altitudes – as high as 10,000 to 15,000 meters (about 33,000
to 49,000 ft).
44. 44
A jumbo jet is a term used to describe a large aircraft, most
commonly the Boeing 747, after Jumbo, a famous elephant.
The 747-400, is among the fastest airliners in service with a high-
subsonic cruise speed of 570 mph, 920 km/h and can accommodate
more than 500 passengers.
46. Transportation EngineeringTransportation Engineering
• One of the specialty areas of civil
engineering
– Development of facilities (roads ,
railways, airports, Bus stops,..) for the
movement of goods and people
– Planning, design, operation and
maintenance
• Multidisciplinary study
47. • Transportation engineering:
• Science deals with efficient, safe, economical, comfortable
and speedy movement of goods and persons.
•
• Highway Engineering:
• It covers the construction of roads and providing the facilities
to road user and planning for safety or road vehicles etc.
•
• Railway Engineering:
• It deals with the lying of the railway track for movement of
heavy locomotives, wagons etc. it deals also with control of
movement with help of station yards.
•
47
48. • River and Harbour Engineering:
• Science deals with the development of docks and harbour
on sea or river shore for departure and arrival of ships and
other facilities for loading, unloading etc.
•
• Airport Engineering:
• Technique of development of runways, taxiways,
hanger, terminal building and control devices etc are dealt
in Airport engineering.
48
52. Development of road:Development of road:
• Road extensively used before advent of railways
• Major roads work ignored but attention on feeder roads.
• End of 2nd
world war provided surplus military vehicles of
civilization.
• Boom to road construction and 1930 -- automobile age
•
• Highway related activities:
– motor vehicle registration
– highway expenditures
– road milage pass-Km, Tonn – Km.
– motor fuel consumption….
52
53. • Infrastructure and Economic
• Growth
• In the following slide a graph is presented that clarifies
the role of
• infrastructure in economic development (Source: Queiroz et
al, 1992
• – World Bank Working Paper).
• This slide shows a plot of the length of paved roads that
a country
• has versus its GNP
• 98 countries were surveyed to plot this graph
• A clear correlation emerged between the Length of
paved roads
53
54. • (LPR) and the per-capita GNP (PGNP) according to the
following
• equation
• PGNP = 1.39 (LPR)
• This indicates that the more physical infrastructure a
country has (in
• this example we consider only transportation infrastructure,
but this
• relationship holds true for other types of infrastructure as
well), the
• greater the economic stability and vice versa.
54
56. The Infrastructure CrisisThe Infrastructure Crisis
• Despite the importance of infrastructure for economic and
social well-being, we are faced with several problems
• Infrastructure in developed countries is old, unreliable,
inefficient and in need of replacement.
• The USA is embarking on a major plan relating to
infrastructure spending
• In developing countries, infrastructure is often not
available
56
57. • Large portions of urban and rural populations in developing
countries haveinadequate access to water and sanitation
• Power supply is non-existent or unreliable and people are faced
with frequent power-cuts
• Quality of road infrastructure is often bad, leading to long
travel times and increased vehicle maintenance costs. Width of
roads is also often a constraining factor leading to traffic jams and
blocks.
• Several of these problems currently hold true for many areas in
India as well.
• This is therefore a golden opportunity for engineers with
technical as well as managerial and policy level knowledge of
these issues, since there is a huge demand for such people to
enter the workforce and solve the worlds infrastructure
inadequacies.
57
58. Why do we have so manyWhy do we have so many
problems with infrastructure?problems with infrastructure?
• This particular question and ways in which to solve it will
• the focus of this entire course. It is therefore impossible
• to answer this question right away. Before we conclude
• this session, we list out a few of the causes for the failure
• to provide adequate infrastructure
• Lack of funds
• Lack of implementation and management capabilities
• Corruption, bureaucracy and unfair competition
• Land acquisition issues involving dealing with displaced
people
• and special interest groups
• etc
58
59. INTRODUCTIONINTRODUCTION
PAKISTAN HIGHWAY SYSTEMPAKISTAN HIGHWAY SYSTEM
PAKISTAN
TRANSPORTATION
SYSTEM
It contributes 11% in country's GDP & 5.46 % in employment
labor force
It accounts for 90% passenger and 96% for freight traffic.
Road transport is to be Considered the backbone of Pakistan
transport.
It Carries about 80% of the Pakistan total transport.
62. PAKISTAN HIGHWAYPAKISTAN HIGHWAY
SYSTEMSYSTEM
• 1947 – 49959Km
• 9759 Km (High type)
• 40200 Km (Low type... Earthen)
•
• 1985 – 118211 Km 5160 Km (High type) Growth Rate 2.29%→
• 1998 – 180000 Km (urban as well as rural)
• 2008-2009 -- 258,350 kms
• 23 National Highways, 7 motorways, 3 expressways & 3
Strategic roads.
• The length of high type road is 176,589kms and low type
road is 81,761kms.
• The total length of National Highways, Motorways,
expressways and strategic roads is 11857kms. Which is
4.6% of total length.
• Quite development but not satisfactory, when compared with
other countries area and population wise. 62
97. 97
Country Length (Km) per
100 Km2
Length (Km) per
1000 Km2
Japan
France
USA
Germany
India
Srilanka
274
174
64
168
50
38
>150
>120
--
>100
Pakistan 14 0.43
Pakistan Poorest Country
Even India has 3 to 4 times greater
Kilometerage
99. Challenges For PakistanChallenges For Pakistan
• Increased traffic volume due to increased vehicle
ownership
• Dire deficiency of 346000Km to serve people
efficiently.
• To widen existing road network from single lane
to two
• If 3000Km constructed every year even then
require 100 years
• Big potential for opportunities for Highway
Engineers.
99
100. Existing Challenges for PakistanExisting Challenges for Pakistan
Now- days over half the road is in poor condition and most of the
roads has been failed before their design life.
Failure is defined in terms of amount of cracking, rut depth, surface
roughness, skid resistance or other indicators
The various factors which may cause the failure of pavement
are:
Overloading
Unsatisfactory Compaction
Inadequate Drainage
Frost action
Quality of Material
The material used does not compliance the specification.
Laboratories do not follow the proper process in testing.
Equipments are not properly working.
End products are not according to specification and give less
results as compared to the required.
This problem can be improved or partially solved by proper
“Quality assurance in testing of highway materials”.
102. Highway Planning:Highway Planning:
• The making of plans and engineering investigation of the
project on a scientific basis rather than haphazard for
future Construction, maintenance and operation (Or for
new project or explained programs) is called Highway
Planning.
• A summary of major Data required for Highway Planning
are:
• An inventory of all rural roads (Width type, condition and
road bridges….)
• An estimate of volume and character of traffic
• Source of highway financing of the state and subdivision.
• An estimate of the number of the motor vehicles
ownership.
• Road life studies based on past records of construction and
reconstruction, from which service life can be estimated.
•
102
103. Object of Highway Planning:Object of Highway Planning:
The proposed road should provide efficient, safe,
economical comfortable and speedy movements.
It should have maximum utility within available
resources and other restraints.
It should meet for anticipated future developments and
social needs.
Highway planning should evolve financing system and
recommend changes in taxes and budget procedures.
Highway Planning helps in phasing the road
development programs from financial consideration and
top most needy condition.
103
104. Principal of Highway Planning:Principal of Highway Planning:
• Equipped with traffic sign boards or
statutory provision for regulation
• Importance of road should be only
on traffic demand
• Road should from integral part of
network and form a part of
development schemes.
• There should be provision of
maintenance funds
104
105. Deficiencies of Highway planning:Deficiencies of Highway planning:
• No correlation to transport needs.
• No any base on systematic transport
survey
• No asses of base and horizon year traffic.
• No evaluation for qualitative
improvements in terms of geometric,
structural integrity, riding surface etc.
• No relation between transport plans with
other sector like agriculture, industry etc.
105
106. STUDIES/ DATA COLLECTIOINSTUDIES/ DATA COLLECTIOIN
REQUIRED FOR EFFICIENT PLANNINGREQUIRED FOR EFFICIENT PLANNING
• Field studies are conducted to collect the
data for assessment of road length
requirement for an area.
• Intelligent approach for efficient planning
• Helps in protecting any project from short
sightedness and shifting policies
• Detailed of surveys/studies are given
below for the development of a road
Project.
106
107. ECONOMIC STUDIESECONOMIC STUDIES
• Following details should be collected for economic studies
to determine the details of services given by the proposed
road to population & products of area which are useful in
estimating the economics involved
• Population and its distribution Trend of population growth
• Agriculture and industrial production and their listing in
classified groups and develop their future trends
• Per capita income
• Existing facilities like post office, School, Banks , etc
(Regarding communication, education and recreation to
estimate the Source of traffic)
• Country Highway mileage, its condition and distribution.
107
108. Financial Studies:Financial Studies:
• It is important to study various financial aspects like source
of income and their methods adopted to mobilize the fund
for project
• Source of income
• Estimating revenue from road transport
• Living standards
• Resources from local level, toll, Vehicle registration and
court fines etc.
108
109. Traffic and road use studies:Traffic and road use studies:
• Details of existing traffic, their volume and the pattern of
flow etc is necessary to plan for improvement in road
system or for construction of new road.
• Traffic Volume per day, AADT and peak hourly traffic
volume
• Origin and destination study.
• Mass transportation facilities
• Accidents, their cost analysis and causes
• Future trend and growth in traffic volume and goods traffic
• Growth of passenger trips and trend in the choice of mode
• Type of vehicle, gross weight, axle load, weight and length
or vehicle , commodity hauled etc are value able for road
design and regulation purpose
109
110. Engineering Studies:Engineering Studies:
• Detail of topography, Soil, Drainage and problems
related to construction and maintenance to be
investigated to chalk out plan. It needs
• Topographic survey
• Road location and alignment studies
• Soil surveys
• Location and classification of existing roads and
their types
• Road life studies, construction methods and
maintenance problems
• Special problems in drainage
110
111. PROJECT REPORT:PROJECT REPORT:
Project report should contain following details
• Introduction of project along with history and graphical
details
• Main requirements and factor of proposed alignment
• Details of alignment with respect to proposed width/
guage , gradients, length and levels of points
• Description about other proposed alternatives
• Details of proposed alignment with various dates and maps
• Specifications of the constructional standards
• Conclusion and recommendation of proposed project of new
railway line / High way.
111
112. Drawing to maps prepared along withDrawing to maps prepared along with
project report:project report:
• Overall map of that region to a scale 1 cm = 2Km.
• Index map of the area to a scale of 1 cm = 2.5 Km.
• detailed plan of proposed alignment with L section
• Contour plans and L section at bridge & culvert
• Plans of Bus stop to scale of 1 cm = 50 cm (Bus stop,
Rest , filling stations, Rest places)
• detailed drawing of all the bridges and buildings to a scale
of 1 cm = 1 m
• plan of level crossings to a scale 1 cm = 50 m
• details of important structures lying with 300 m on either
sides of the proposed rout
• Cross section at every important point should be prepared.
112
115. Corridor StudyCorridor Study
The objective of the corridor study (highway
location study) is to establish highway's
centerline (baseline) and cross-sections in
relation to the terminal points and to the
topography of the area through which the
highway will pass.
The proposed highway route must be:
1. Economically justifiable,
2. Technically feasible, and
3. Environmentally acceptable.
116. 116
Basic Principles for HighwayBasic Principles for Highway
LocationLocation
• There are an infinite number of ways to get from point A to
point B.
• selecting the best path between two points is called
Highway location
• Visible features of a road are Straight section; Transition
curve; Circular curve; Vertical curve; Cross-sections
• Visible features Roadway must be connected with each
other to design a road that provides for the easy flow of
traffic, while meeting design criteria and safety
standards.
Garber and Hoel, 2002
117. 117
Factors Considered in the Selection ofFactors Considered in the Selection of
the best routthe best rout
• Topography
• Social and demographic characteristics
(including land use patterns)
• Terrain and soil conditions
Garber and Hoel, 2002
118. 118
Factors Considered in the LocationFactors Considered in the Location
ProcessProcess
• Directness of route
• Serviceability of route to industrial and
population areas
• Crossing of other transportation facilities (roads,
railroads, rivers)
– Intersect other roads at right angle
Garber and Hoel, 2002
119. 119
Factors Considered in the LocationFactors Considered in the Location
ProcessProcess
• Environmental
– Animal habitat
– Location of recreational, historic and
archeological sites
– Noise, air, and water pollution
Garber and Hoel, 2002
120. 120
Factors Considered in the LocationFactors Considered in the Location
ProcessProcess
• Economic
– Construction
– Maintenance costs
– Road user costs
– Road user benefits (i.e. travel time)
– Adverse effects such as dislocation of
people or businesses
Garber and Hoel, 2002
122. ENGINEERING SURVEY FOR HIGHWAYENGINEERING SURVEY FOR HIGHWAY
LOCATIONLOCATION
• This survey is also called Route Survey and propose is to fix
the final road alignment
• and carried out in four stages.
• Map study
• Reconnaissance survey (Recci) Survey
• Preliminary survey
• Final location and detailed survey
122
130. Map Study:Map Study:
• It suggests the possible routes of the projected road out of
several likely alternative routes from available
• It gives the rough guidance about the route to be further
survey in the field
• The main features likes rivers hills valleys etc available on
maps helps in locating the alignment roughly avoiding
ponds and lakes.
• Give idea about approximate location of bridges, tunnels
etc.
• From map study it is also possible to drop a certain route
due to unavoidable obstructions.
• Topographic map having 15 or 30 meter contour intervals
could be used for this study.
130
131. ::
Recci SurveyRecci Survey
• The main object of Recci survey is to examine in the field
the general characteristics of a stretch of land along the
proposed alternatives routes marked on the map.
• Following facts (not available in maps) are collected during
recci survey.
• e.g. Marshy land, ridge, hills, permanent structures and
other type of cross drainage structures, soil type along the
route, proximity of materials and labor etc.
• For that survey plans, land use plans, air photos, stream
and drainage maps etc. are used.
• As a result of recci survey a few alternative alignment (two
or three)may be chosen for further study.
• Recci survey is not required for minor relocation of an
existing road.
131
132. Preliminary Survey:Preliminary Survey:
• The preliminary survey decides the final route among two
or three routes after studying the advantages and
disadvantages.
• It is carried about with great accuracy and with critical
study
• Because the final route selection depends upon it and has
much effect on investment.
• Generally preliminary survey work is more or less an open
traverse survey of 60 to 300 meters wide belt along the
centre line of proposed (2 or 3) alternatives.
•
132
133. Preliminary SurveyPreliminary Survey
Preliminary Survey is done especially to collect below
information
• Geological information like soil, rocks, etc and their bearing
capacity
• Details of existing culverts, bridges, tunnels, irrigation
canal works etc.
• Position and details of level crossing proposed.
• Availability of construction material, labors, water along
proposed alignment.
• H.F.L. and L.W.L. of all river streams on paved alignment.
• Preliminary survey work is done mostly with Tachometer,
Level instrument, Prismatic compass and Plane table.
133
134. Preliminary SurveyPreliminary Survey
• All physical features e.g. building, posts of existing roads
and their radius of horizontal curves should be marked and
measured from transverse line.
• Grades at every 50m interval.
• Cross section at every 500m intervals.
• In order to have general idea to final centre line of
alternative alignment conforming to the design standards is
tried on plans.
• More suited alternatives from economic and other
consideration is finally chosen.
134
135. Location Survey:Location Survey:
• Here full detailed survey work will be done along most
economical route, determined by the preliminary survey.
• The final route marked on prepared plan is known paper
location, in which details of gradient, curves, contour,
direction crossing of streams etc are worked out.
• Then transfer of alignment from paper to ground is done in
the Final location Survey.
135
136. Final Location SurveyFinal Location Survey
• It consists in fixing up the centerline of the proposed
highway on the ground with the horizontal and vertical
controls. Final location involves two main operations.
• Sketching out of final centerline of the field.
• Beginning and end of circular and transition curves and all
other intermediate transit points (250m C/C) should be
fixed on center in case of new roads or by means of spikes
in the case of existing road.
• A single datum should be used for level works.
• Permanent bench marks should be established at every
250m, and at all drainage structure or on famous
reference point.
136
137. Final Location SurveyFinal Location Survey
– Detailed cross section at stations every 50m in plain
and at 25m in rolling terrain apart should be taken.
– In addition above other cross sections at the
beginning, middle and at end of spiral and of
circular curves should be taken up to the right-of-way
limits.
Detailed leveling.
– Longitudinal profile should also be taken for a stretch at
least 200m beyond then limit of the project.
• After protecting the points referencing Centre line the
construction survey is started.
137
139. 139
HOW IS HIGHWAYHOW IS HIGHWAY
LOCATION DETERMINED?LOCATION DETERMINED?
When Your Land Is Needed For Highway Use
Author: Stephen D. Holowach 7/23/99
http://www.119south.com/presentation/
• Establish the most direct and useable highway facility
at the least possible cost to the public.
• For undertakes intensive studies on several possible
routes
• Select the route that has the least possible
inconvenience or injury to the public and the private
landowner.
• Analyze the data concerning the economy, population
needs and traffic volume trends for the area under
study.
• Make the Aerial and ground surveys to consider factors
such as safety, drainage and soil types.
• Hold the public meetings to discuss the proposed
alternate locations.
140. 140
RIGHT-OF-WAY?RIGHT-OF-WAY?
• Right-of-Way is the term used to describe the right
to pass over another’s land.
• When the government acquires land for Highway
Purposes it is actually obtaining “Right-of-Way” over
land on which a public road ultimately will be built.
• It is a Constitutional right of the government to
acquire land for public purposes
• The every Department of Transportation will execute
this right only when it will benefit the public.
141. 141
What does a location study include?What does a location study include?
http://www.virginiadot.org/projects/studybris-http://www.virginiadot.org/projects/studybris-
coalfieldprocess.aspcoalfieldprocess.asp
Fully defining the project, or "scoping“
•This process is an opportunity to identify
issues and obtain comments from
agencies, jurisdictions and the public
early in the planning process.
•A "purpose and need" statement and the
goals and objectives of the Location Study
will be developed.
142. 142
What does a location study include?What does a location study include?
(VDOT)(VDOT)
http://www.virginiadot.org/projects/studybris-http://www.virginiadot.org/projects/studybris-
coalfieldprocess.aspcoalfieldprocess.asp
Alternatives Identification
•Use technical data such as traffic counts and aerial
mapping and early environmental evaluations to develop
several possible road locations, or alternatives, within the
Study corridor.
•In this phase is to identify reasonable alternatives that
consider the input provided from communities, businesses
and individuals as well as regional concerns.
•Consider a number of new locations as well as upgrades
of existing roads.
•Look at the deficiencies of the existing transportation
network, including safety concerns and any planned
improvements along the study corridor.
147. 147
4 ACTIVITIES4 ACTIVITIES
1. The existing physical
structure needs major
repair/replacement
(structure repair).
http://www.k5kj.net/jarrell.htm
148. 148
4 ACTIVITIES4 ACTIVITIES
2. Existing or projected
future travel demands
exceed available
capacity, and access to
transportation and
mobility need to be
increased (capacity).
http://www.ens-
newswire.com/ens/sep2002/2002-09-19-
06.asp
149. 149
4 ACTIVITIES4 ACTIVITIES
3. The route is experiencing
an inordinate number of
safety and accident
problems that can only
be resolved through
physical, geometric
changes (safety).
http://www.ems.ucla.edu/traffic/
ta10.htm
150. 150
4 ACTIVITIES4 ACTIVITIES
4. Developmental pressures
along the route make a
reexamination of the
number, location, and
physical design of access
points necessary
(access).
152. Geometric DesignGeometric Design
• Geometric design is the aspect of
transportation engineering that deals with
• A) Selection of the best path between two
destinations.
• B) Deals with the design of visible features
of a road
• A good geometric design has to balance
balance operational efficiency, comfort,
safety, convenience, cost, environmental
impact, and aesthetics.
152
153. Geometric DesignGeometric Design
• Geometric design deals with the
design of visible features
• Visible features are
– Straight section
– Transition curve
– Circular curve
– Vertical curve
– Cross-sections
153
173. DesignDesign VehicleVehicle
A design vehicle represents an individual
class in a conservative manner.
• passenger cars (compact, subcompact,
light delivery trucks),
• trucks (single-unit, tractor-semitrailer
combinations, trucks with full trailers),
• buses/recreational vehicles (single-
unit, articulated, school buses, motor
homes, passenger cars pulling trailers or
boats).
174. 174
Design VehicleDesign Vehicle
• Design Vehicle – largest (slowest,
loudest?) vehicle likely to use a facility
with considerable frequency
• Three characteristics that affect almost
all aspects of highway design
– Physical
– Operating
– Environmental
175. 175
Physical CharacteristicsPhysical Characteristics
• Type (GB defines 20 design vehicle types)
– Passenger Car P
– Buses B
– Trucks SU, WB
– RVs
– Farm tractor
• Size
– Length
– Height
– Weight
– Width
– Height of driver’s eye (car: 3.5’ – avg., truck: 7.6’ –
high side)
– Center of mass
177. Minimum Turning PathMinimum Turning Path
Passenger CarPassenger Car
Minimum turning path
is defined by the
outer trace of the
front overhang and
the path of the inner
rear wheel.
191. Vehicles on GradesVehicles on Grades
• Passenger cars
– The upgrades up to 3% have a slight impact on
passenger cars.
– On steeper grades this effect becomes more
pronounced.
– No special consideration is needed.
• Trucks
– The effect of grades on truck speeds can be quite
strong (Exh. 3-53, 3-60).
– The truck with the mass/power ratio 120 kg/kW is
selected to represent heavy vehicles (conservative
assumption).
• Recreational vehicles
– Consideration of recreational vehicles on grades can
be justified for recreational roads with the low
percent of trucks (for example, to consider an
additional lane).
192. Effect of grade on truckEffect of grade on truck
performanceperformance
Crawling
speed
200. 200
ObjectivesObjectives
Get familiar with design speeds
for functional classes
Describe traffic demand and
determine for roadway design
Define ADT, AADT, DHV, D,
DDHV, K-Factor, and T
201. 201
• Posted speed = speed limit
• Operating speed = free flow (spot
speed)
• Running speed = length of
highway section ÷ running time
• Design speed = selected speed
used to determine geometric
design features
202. Design speedDesign speed
• Design speed is the single most important factor
that affects the geometric design.
• It directly affects the sight distance, horizontal
curve, and the length of vertical curves.
• Since the speed of vehicles vary with driver,
terrain etc, a design speed is adopted for all the
geometric design.
• Design speed is defined as the highest continuous
speed at which individual vehicles can travel with
safety on the highway when weather conditions
are conducive.
202
203. Design speedDesign speed
• Design speed is different from the legal speed
limit which is the speed limit imposed to curb a
common tendency of drivers to travel beyond an
accepted safe speed.
• Design speed is also different from the desired
speed which is the maximum speed at which a
driver would travel when unconstrained by either
traffic or local geometry.
203
204. Design speedDesign speed
• Since there are wide variations in the speed adopted by
different drivers, and by different types of vehicles, design
speed should be selected such that it satisfy nearly all
drivers.
• At the same time, a higher design speed has cascading
effect in other geometric designs and thereby cost
escalation.
• Therefore, an 85th percentile design speed is normally
adopted.
• This speed is defined as that speed which is greater than
the speed of 85% of drivers. In some countries this is as
high as 95 to 98 percentile speed.
204
205. 205
Design SpeedDesign Speed
Design speed is defined by the AASHTO Green
Book as: ...the maximum safe speed that
can be maintained over a specified
section of highway when conditions are
so favorable that the design features of
the highway govern.
Design Speed should: 1) “…be consistent
with the speed the driver is likely to expect.”
and 2) “. . .fit the travel desires and habits of
nearly all drivers.”
Not posted speed and not operating speed
(but ALWAYS higher than both)
See first part of:
http://www.fhwa.dot.gov/environment/flex/c
h04.htm (Chapter 4 from FHWA’s Flexibility in
Highway Design)
206. 206
Design Speed ConsiderationsDesign Speed Considerations
• Functional classification of the highway
• Character of the terrain
• Density and character of adjacent land
uses
• Traffic volumes expected to use the
highway
• Economic and environmental
considerations
207. 207
Design Speed in Green BookDesign Speed in Green Book
(suggested minimum design speed)(suggested minimum design speed)
Rural Local Roads
Source: A Policy on Geometric
Design of Highways and Streets
(The Green Book). Washington, DC.
American Association of State
Highway and Transportation
Officials, 2001 4th
Ed.
208. 208
Design Speed in Green BookDesign Speed in Green Book
(suggested minimum design speed)(suggested minimum design speed)
Rural Collectors
Source: A Policy on Geometric
Design of Highways and Streets
(The Green Book). Washington, DC.
American Association of State
Highway and Transportation
Officials, 2001 4th
Ed.
209. 209
Design Speed in Green BookDesign Speed in Green Book
(suggested minimum design speed)(suggested minimum design speed)
Rural Arterials
60 – 120 kph (40-75 mph)
Depends on …
Terrain
Driver expectancy
Alignment (reconstruction)
210. 210
Design Speed in Green BookDesign Speed in Green Book
(suggested minimum design speed)(suggested minimum design speed)
Urban
• Locals 20-30 mph
• Collectors 30 mph+
• Arterials 30-60 mph
211. 211
Values represent the
minimum acceptable
design speeds for the
various conditions of
terrain and traffic
volumes associated
with new or
reconstructed
highway facilities
214. 214
Traffic DefinitionsTraffic Definitions
• Volume:
– number of vehicles, pedestrians, etc.
passing a point during a specific
period of time
– for vehicles, usually expressed as
veh/hour (vph) or veh/hour/lane
(vphpl)
215. 215
• Demand:
– number of vehicles, pedestrians, etc. that desire to
travel between locations during a specific period
– Frequently higher than volume during certain peak
times
– Trips are diverted or not made when there are
constraints in the system
– difficult to measure actual demand because capacity
constrains the demand
• Capacity:
– maximum number of vehicles that can pass a point
during a specific period
– A characteristic of the roadway or facility
216. 216
Characteristics of Traffic FlowCharacteristics of Traffic Flow
• Highly variable
– Time of day
– Day of week
– Season
– Road characteristics
– Direction
218. 218
Volume StudiesVolume Studies
• AADT: Annual average daily traffic
(counted for 365 days)
• ADT: average daily traffic (counted
for > 1 day and < 365)
• PHV: peak hour volume
• Classification counts: fleet mix
219. 219
Estimating AADTEstimating AADT
• Annual Average Daily Traffic
• Use count station information
• Extrapolate to non-count locations
• Used to adjust ADT for
– Seasons
– Daily variation
220. 220
AADT Data Helps to:AADT Data Helps to:
• Estimate highway revenues
• Establish overall volume trends
• Establish annual accident rates
• Analyze benefits of road
improvements
221. 221
Counting ProgramCounting Program
• To satisfy the traffic volume data
needs for all roads under a particular
jurisdiction, we establish a Counting
Program
A systematic pattern of counting
at different times and locations
224. 224
Design VolumeDesign Volume
• Usually hourly volume
• Which hour?
– Average hourly volume – inadequate design
– Maximum peak hour – not economical
– Hourly volume used for design should not be
exceeded very often or by very much
– Usually use 30th
highest hourly volume of the
year
– On rural roads 30 HHV is ~ 15% of ADT
– Tends to be constant year to year
225. 225
Traffic DemandTraffic Demand
Design Hourly Volume (DHV) – future
hourly volume (both directions) used
for design - typically 30th
HHV (highest
hourly volume) in the design year
Why 30th
HHV?
Breakpoint of 2-28
Compromise: too high is wasteful, too
low poor operation
Approximately median weekly peak hour
volume (top highest week peak hours)
(30th
HHV exceed 29 times in year)
226. 226
Traffic Demand (cont.)Traffic Demand (cont.)
3. Exhibit 2-28 relationship between HHV and percent of
ADT in peak hour (referred to as K-factor)
Source: A Policy on
Geometric Design of
Highways and Streets
(The Green Book).
Washington, DC.
American Association of
State Highway and
Transportation Officials,
2001 4th
Ed.
227. 227
Design Hourly VolumeDesign Hourly Volume
DHV is a representation of peak hour traffic,
usually for the future, or horizon year
K-factor represents proportion of AADT that
occurs in the 30th
HHV
K-factor = __DHV x 100
AADT
K = 8 to 12% urban, 12 to 18% rural
228. 228
Design Hourly Volume (Example)Design Hourly Volume (Example)
If AADT is 3500 vpd and the 30th
highest hourly volume for the year is
420 vph what is the K-factor for that
facility?
K-factor = __DHV x 100
AADT
K-factor = __420 x 100 = 12
3500
229. 229
Question: What’s the impact of choosingQuestion: What’s the impact of choosing
different K factor for design?different K factor for design?
If AADT is 3500 vpd, how will the design volume differ for K-
factor = 8% vs. 12%?
DHV = K-factor x AADT
100
DHVk=8% = 8 x 3500 = 280 vph
100
DHVk=12% = 12 x 3500 = 420 vph (diff of 140
100 veh)
230. 230
Traffic Demand (cont.)Traffic Demand (cont.)
• D = directional distribution = one
way volume in peak direction
(expressed as a percentage of two-
way traffic) Rural 55 to 80%
• Can also adjust for how traffic is
distributed between lanes (e.g., 3
lanes, highest/outside lane may be
40% of total directional flow)
231. 231
Directional DistributionDirectional Distribution (example)(example)
If traffic is directionally split 60/40, what is directional distribution of
traffic for previous example (Design hourly volume = 420 veh/hr)?
Directional Design Hourly Volume (DDHV) =
0.6 x 420 = 252 veh/hr
Notice we use 0.6 not 0.4!!
232. 232
Traffic Demand (cont.)Traffic Demand (cont.)
• T = percentage of heavy vehicles during
design hour (Iowa interstate 35% plus)
• Affects capacity, ability to pass on two-
lane rural roads, etc.
• Larger, occupy more space
• Should determine % during design hour
(truck patterns may not be same as
passenger vehicles)
233. 233
PHF = peak-hour volume
4(peak 15-min volume)
Flow is not uniform throughout an hour
HCM considers operating conditions
during most congested 15-minute
period of the hour to determine service
level for the hour as a whole
Peak Hour Factor (PHF)Peak Hour Factor (PHF)
235. 235
DHV = Peak-Hour Volume
PHF
Example
Peak hour volume from previous = 375
vph
PHF = 0.625
DHV = 375 = 600 vph
0.625
Note: the traffic you design for is the
busiest 15 minutes during the peak
hour … another way to think of it is 150
vehicles per 15 minutes = 600 vehicles
per 60 minutes
240. 240
Design Driver CharacteristicsDesign Driver Characteristics
Cont.Cont.
• Others?: age, gender, physical
condition (alcohol, etc.), mental
capabilities, skill (self perception – are
you in the top ½ of driver skill?)
• Two others related to design:
perception-reaction time and
expectancy
241. 241
Design DriverDesign Driver
• Wide range of system users
• What range of drivers use the
system?
– Ages: 16 year old to 80 year old
– Different mental and physical states
– Physical (sight, hearing, etc)
– experience
• Design Driver: driver most expected
to use facility
244. 244
Visual ReceptionVisual Reception
• Visual Acuity: Ability to see fine details
• Static (stationary objects):
–Depends on brightness
–Increases with increasing brightness
up to ~ 3 candles (cd/sq ft) --
remains constant after that
–Contrast
–Time (0.5 to 1.0 second)
• Dynamic (ability to detect moving
objects)
–Clear vision within a conical angle 3 to
5º
–Fairly clear within 10 to 12º
–Key criteria in determining
placement of traffic signs
245. 245
Visual ReceptionVisual Reception
• Peripheral Vision: Ability to see objects
beyond the cone of clearest vision (160
degrees)
– Age dependent
– Objects seen but details and color are not
clear
246. 246
Visual ReceptionVisual Reception
• Color Vision: Ability to differentiate
one color from another
– Lack of ability = color blindness
– Combinations to which the eye is the
most sensitive
• Black and white
• Black and yellow
y in determining traffic signs colors
247. 247
Visual ReceptionVisual Reception
• Depth perception
– Ability to estimate speed and distance
•Passing on two-lane roads
•Signs are standardized to aid in
perceiving distance
251. 251
Perception-Reaction ProcessPerception-Reaction Process
• Perception
– Sees or hears situation (sees deer)
• Identification
– Identify situation (realizes deer is in
road)
• Emotion
– Decides on course of action (swerve,
stop, change lanes, etc)
• Reaction (volition)
– Acts (time to start events in motion
but not actually do action)
• Foot begins to hit brake, not actual
deceleration
254. 254
Perception-Reaction TimePerception-Reaction Time
FactorsFactors
• medical condition
• visual acuity
• ability to see (lighting conditions, presence
of fog, snow, etc)
• complexity of situation (more complex =
more time)
• complexity of necessary response
• expected versus unexpected situation
(traffic light turning red vs. dog darting
into road)
256. 256
Perception Reaction Time (PRT)Perception Reaction Time (PRT)
• Time from Perception to Initial
Reaction to Stimulus (Example)
257. 257
AgeAge
• Older drivers
– May perceive
something as
a hazard but
not act quickly
enough
– More difficulty
seeing,
hearing,
reacting
– Drive slower
258. 258
AgeAge
• Younger drivers
– May be able to act quickly but not have
experience to recognize things as a hazard
or be able to decide what to do
– Drive faster
– Are unfamiliar with driving experience
– Are less apt to drive safely after a few
drinks
– Are easily distracted by conversation and
others inside the vehicle
– May be more likely to operate faulty
equipment
– Poorly developed risk perception
– Feel invincible, the "Superman Syndrome”
Human Factors - Perception and Reaction
by Joseph E. Badger. jebadger@harristechnical.com
259. 259
AlcoholAlcohol
• Affects each person differently
• Slows reaction time
• Increases risk taking
• Dulls judgment
• Slows decision-making
• Presents peripheral vision
difficulties
Human Factors - Perception and Reaction
by Joseph E. Badger. jebadger@harristechnical.com
260. 260
ExperienceExperience
• Even NASCAR drivers practice
Familiarity
Faster on familiar
Unfamiliar more distracted
– Rental car on unfamiliar road at 10 pm when it starts
to rain (What is the driver doing?)
265. 265
UnderstandingUnderstanding
• Most people do not reduce speed
in a work zone until they actually
see activity
• Only 78% of drivers in a study
understood what “Lane Ends”
mean
• Many people, especially older
drivers, don’t understand meaning
of left turn displays
Human Factors - Perception and Reaction
by Joseph E. Badger. jebadger@harristechnical.com
266. 266
FatigueFatigue
• Increases perception/reaction
time
• Study by American
Automobile Association found
that in 221 truck accidents
only 18.4% of the drivers had
been driving less than nine
hours.
• 41% of truck accidents
Human Factors - Perception and Reaction
by Joseph E. Badger. jebadger@harristechnical.com
268. 268
How much longer does it take an impaired driver to
perceive/react than an unimpaired one at 65 mph?
Unimpaired has P/R time of 2.5 seconds
Dp
= 1.47(V)(t) =
1.47(65 mph)(2.5 sec.) ~ 240 feet
Impaired Driver has P/R time of 4 seconds
Dp
= 1.47(65 mph)(4 sec) ~ 380 feet
Difference is 380 – 240 = 140 feet
Difference is safety and economic problem!
Example
271. 271
Driver ExpectancyDriver Expectancy
• Expectancy (def) – an inclination based
on previous experience to respond in a
set manner to a roadway, traffic, or
information situation
• Types
– A Priori – long-term (based on
collective past experience) PRT =
0.6s avg., some 2.0s
– Ad Hoc – short-term (based on site-
specific practices/situations
encountered during a particular trip
on a particular roadway, PRT = 1.0s
avg., some 2.7s
272. 272
Driver ExpectancyDriver Expectancy
• Driver Expectancies (what do we
expect as drivers?)
– Specific colors (red = stop)
– Driver ahead not to decelerate rapidly
– Slower drivers in left lane
– Work zone signs = people working
– Lane size
– Etc.
275. 275
The 85th
percentile is generally
used to select Design Criteria
The 95th
percentile or higher is
used where the consequences
of failure are severe
AASHTO recommends 2.6
seconds for stopping sight
distance (90th
)
276. 276
RRole of Transportationole of Transportation
EngineerEngineer
• allow proper sight
distance in design,
sign placement
• avoid hitting driver
with too much info
at once
– one sign at a time
• clarity (sign size,
color, reflectivity)
277. 277
Driver Activities in Selection ofDriver Activities in Selection of
PathPath
• Control (overt actions)
– Road Edge
– Avoid a Car
• Guidance (decisions)
– Lane Placement
– Car Following
– Passing
278. 278
Driver Activities in Selection ofDriver Activities in Selection of
Path Cont.Path Cont.
• Navigation Level (planning)
– Maps
– Observe a directional sign
280. 280
Important Sight DistancesImportant Sight Distances
1. Stopping
2. Decision
3. Passing
4. Intersection
5. Crossing RR
FIRST AND THIRD WILL BE DISCUSSED
HERE
281. 281
Sight Distance in DesignSight Distance in Design
• For safety, should provide sight distance
of sufficient length so that drivers can
control the operation of their vehicles to
avoid striking an unexpected object in the
traveled way - STOPPING SIGHT
DISTANCE (SSD)
• Certain 2-lane roads should have sufficient
sight distance to enable drivers to occupy
the opposing traffic lane for passing other
vehicles without risk of crash - PASSING
SIGHT DISTANCE (PSD)
282. 282
Green Book (AASHTO)Green Book (AASHTO)
Policy QuestionPolicy Question
• Sight distance assumes drivers are
traveling at:
– A. The posted speed limit
– B. 10 mph above the speed limit
– C. The 85% percentile spot speed of
the facility
– D. The design speed of the facility
283. 283
Design Policy - ResponseDesign Policy - Response
• Sight distance assumes drivers are
traveling at:
– A. The posted speed limit
– B. 10 mph above the speed limit
– C. The 85% percentile spot speed of
the facility
– D. The design speed of the facility
284. 284
GB Question with responseGB Question with response
• Stopping sight distance is composed
of two distances, what are they?
– Distance traveled during
perception/reaction time
– Distance required to physically brake
vehicle
285. 285
Studies onStudies on
Perception/Reaction TimePerception/Reaction Time
• 321 drivers (Johansson and Ruma):
drivers expected to use brakes
– Median: 0.66 sec
– 90th
percentile: >= 1.5 sec
• Unexpected, response time increased by ~
1 sec
• Some drivers took over 3.5 seconds to
respond even under simple test condition
286. 286
GB QuestionGB Question
• AASHTO GB recommends 2.5
seconds, this is adequate for
conditions that are more complex
than the simple conditions used in
laboratory and road tests.
287. 287
Sight distanceSight distance
Distance a driver can see ahead at
any specific time Must allow
sufficient distance for a driver to
perceive/react and stop, swerve etc
when necessary
288. 288
Stopping Sight DistanceStopping Sight Distance
(SSD)(SSD)
Required for every point
along alignment
(horizontal and vertical) –
Design for it, or sign for
lower, safe speed
Available SSD =
f(roadway alignment,
objects off the alignment,
object on road height
SSD = PRT + BD (with
final velocity V2
= 0)
289. 289
Criteria for Sight DistanceCriteria for Sight Distance
• Driver eye height: for passenger
vehicle’s = 3.5 ft above surface
• Height of object in roadway = 2 feet
(SSD)
• Height of opposing vehicle = 3.5 feet
(PSD)
290. 290
Deceleration rate: AASHTO: 11.2 ft/s2
Deceleration is within capability of drivers
to stay within their lane and control the
vehicle when braking on wet surfaces and
is comfortable for most drivers
• AASHTO represents friction as a/g
which is a function of the roadway, tires,
etc
• Can use when deceleration is known
(usually not)
291. 291
BD = V2
30[ (a) ± G]
(g)
Where:
BD = braking distance (ft)
V = speed (mph) (can also be “u”)
a = deceleration rate (ft/s2
)
G = grade (decimal)
g = acceleration due to gravity =32.2 ft/s2
292. 292
Braking DistanceBraking Distance
Assumes a rate of deceleration, driver may brake harder
a = 11.2 ft/sec2
normal
a = 14.8 ft/sec2
emergency, use tables from AASHTO
Friction is a function of pavement condition (wet, icy), tire,
and roadway surface
Depends on weight, but some assumptions are made to
arrive at a standard equation
293. 293
SSD EquationSSD Equation
SSD = 1.47ut + _____u2
_____
30({a/g} ± G)
SSD in feet
u speed in mph (may also see “v”)
t perception/reaction time (in seconds)
a assumed deceleration rate (ft/sec2
)
g gravitational force (32.2 ft /sec2
)
G gradient in ft/ft
294. 294
SSD ExampleSSD Example
Use basic assumptions to determine SSD at 60 mph on
a) 0% grade, b) 3% grade
SSD = 1.47u(2.5 sec) + ________u2
________
30({11.2/32.2} + 0.00)
SSD = 220.5 + 345.5 = 556 ft
(compare to table 3-1 in GB – See next slide)
On a +3% grade, SSD = 220 +318 = 538 ft
295. 295
Stopping
(emergency) –
SSD (Table 3-1)
Source: A Policy on Geometric Design of
Highways and Streets (The Green Book).
Washington, DC. American Association of
State Highway and Transportation Officials,
2001 4th
Ed.
296. 296
SSD ExampleSSD Example
Given: Available Sight distance = 430’ on a +3% grade
Find maximum speed if perception reaction time is assumed to be 2.5
seconds
430 feet = 1.47u(2.5 sec) + ________u2
________
30({11.2/32.2} + 0.03)
430 feet = 3.68u + ________u2
________
30(0.378)
Solving for u, u = 52.0 mph (Set speed at 50
mph)
Discuss: Would this be an acceptable condition if
the road is generally posted for 60 mph?
297. 297
Stopping Sight DistanceStopping Sight Distance
ExampleExample
Consider analysis when vehicle skids
across different surfaces (a/g is not
equal to 0.35)
Or final velocity is not zero at the end of
the skid, as evidenced because the
vehicle sustains crushing damage until
the vehicle is stopped.
298. 298
Stopping Sight DistanceStopping Sight Distance
where:
terms are as before, except
vo = original velocity
vf = final velocity at impact
With assumed acceleration, using friction
S = PRD + Db
= 1.47vot + vo2
- vf2
30(f ± G)
299. 299
Stopping Sight DistanceStopping Sight Distance
ExampleExample
Accident Reconstruction:
Average Skid Mark = 47 feet
Crush damage indicates 20 to 30 mph speed at impact
f = 0.65 (how do they know this?), level roadway, and 40 mph posted
speed.
Was vehicle speeding?
47 feet skid represents what? BD?
If final speed is 30 mph …
BD = 47 = (Vi
2
– 302
)/30(0.65 + 0)
Vi
= 42.6 mph
If final speed is 20 mph (Vi
= 36.3 mph)
What if pavement changes to gravel after 47 feet and car slides
another 30 feet (f = 0.7)? What is initial speed?
300. 300
Typical values for frictionTypical values for friction
Values of friction vary widely with road
surface type, age, condition. Examples:
Surface type f (or a/g)
Concrete pavement -dry 0.60 to .75
Concrete pavement – wet 0.45 to .65
Asphalt pavement 0.55 to .70
Gravel 0.40 to .70
Ice 0.05 to .20
Snow 0.30 to .60
Source: Lynn Fricke, Northwestern Univ.
301. 301
Decision Sight DistanceDecision Sight Distance
• SSD are sufficient to allow reasonably
competent and alert drivers to come to a
hurried stop under ordinary circumstances
• May be inadequate when drivers must
make complex or instantaneous decisions,
when information is difficult to perceive or
when unexpected or unusual maneuvers
are required
• Equations in book, use tables
302. 302
Decision Sight DistanceDecision Sight Distance
• When situation is unexpected or
driver must make unusual maneuvers
or under difficult-to-perceive
situations
• Requires higher P/R time
• Depends on type of maneuver
made and roadway setting (urban vs.
rural)
• Use table 3.5 from Text, page 75
303. 303
Decision
(controlled stop, speed/path/route change) – DSD (Table 3-3)
Source: A
Policy on
Geometric
Design of
Highways and
Streets (The
Green Book).
Washington,
DC. American
Association of
State Highway
and
Transportation
Officials, 2001
4th
Ed.
304. 304
Passing Sight DistancePassing Sight Distance
Assumptions (conservative?):
1. Vehicle being passed travels at uniform speed
2. Speed of passing vehicle is reduced behind passed
vehicle as it reaches passing section
3. Time elapses as driver reaches decision to pass
4. Passing vehicle accelerates during the passing
maneuver and velocity of the passing vehicle is 10
mph greater than that of the passed vehicle
5. Enough distance is allowed between passing and
oncoming vehicle when the passing vehicle returns
to its lane
305. 305
Source: A
Policy on
Geometric
Design of
Highways and
Streets (The
Green Book).
Washington,
DC. American
Association of
State Highway
and
Transportation
Officials, 2001
4th
Ed.
306. 306
Passing Sight DistancePassing Sight Distance
Dpassing = d1 + d2 + d3 + d4
d1 = distance traveled during P/R time to point where
vehicle just enters the left lane
d1 = 1.47t1(u – m + at1)
2
where
t1 = time for initial maneuver (sec)
u = average speed of passing vehicle (mph)
a = acceleration (mph/s)
m = difference between speeds of passing and
passed vehicle
307. 307
Passing Sight DistancePassing Sight Distance
Dpassing = d1 + d2 + d3 + d4
d2 = distance traveled by vehicle while in left lane
d2 = 1.47ut2
where:
u = speed of passing vehicle (mph)
t2 = time spent passing in left lane (sec)
308. 308
Passing Sight DistancePassing Sight Distance
Dpassing = d1 + d2 + d3 + d4
d3 = clearance distance varies from 110 to 300 feet
d4 = distance traveled by opposing vehicle during passing
maneuver
d4 usually taken as 2/3 d2
309. 309
Important Sight DistancesImportant Sight Distances
(cont.)(cont.)
4. Intersection (turning/crossing)
5. Crossing RR
1. Stop, proceed, proceed from stop
312. 312
Key issues in safe crossingKey issues in safe crossing
Speeds
D Distance from front of vehicle to driver’s eye
Dt Distance from rail to front of vehicle
Vv Assumptions about PR time and braking distance
W Width of crossing
D Distance from end of vehicle after crossing
L Length of vehicle
Acceleration capability of road vehicle
Offset of obstruction from the road and the rail line
313. 313
HomeworkHomework
Go to the example on slide 24. Calculate the vehicle
speed if the roadway is gravel.
Next calculate the vehicle speed on the paved roadway,
but with snow and ice on the road (f = 0.30).
Show your work and discuss how much a driver should
reduce his/her speed for ice and snow on the paved road.