• ♦Manual Notice 2022-2
• ►Preface
• ►1. Design General
  • ►1. Overview
    • ♦Application of Design Guidelines
    • ♦Roadway Design Manual Format
    • ♦External Reference Documents
  • ►2. Design Exceptions, Design Waivers, Design Variances, and Texas Highway Freight Network (THFN) Design Deviations
    • ♦Overview
    • ♦Design Exceptions
    • ♦Design Waivers
    • ♦Design Variances
    • ♦Texas Highway Freight Network (THFN) Design Deviations
  • ►3. Schematic Development
    • ♦Overview
    • ♦Schematic Development Process
    • ♦Schematic Layout
    • ♦Schematic Approval
  • ♦4. Access to the Interstate System
  • ♦5. Preliminary Design
  • ♦6. Maintenance Considerations in Design
• ►2. Basic Design Criteria
  • ►1. Overview
    • ♦Introduction
  • ►2. Functional Classifications
    • ♦Overview
  • ►3. Traffic Characteristics
    • ♦Overview
    • ♦Traffic Volume
    • ♦Speed
    • ♦Terrain
    • ♦Safety
    • ♦Additional Considerations
  • ►4. Sight Distance
    • ♦Overview
    • ♦Stopping Sight Distance
    • ♦Decision Sight Distance
    • ♦Passing Sight Distance
    • ♦Intersection Sight Distance
    • ♦Sight Distance at Under-Crossings
  • ►5. Horizontal Alignment
    • ♦Overview
    • ♦General Considerations for Horizontal Alignment
    • ♦Curve Radius
    • ►Superelevation Rate
    • ♦Sight Distance on Horizontal Curves
  • ►6. Vertical Alignment
    • ♦Overview
    • ♦Grades
    • ♦Vertical Curves
    • ♦Grade Change without Vertical Curves
    • ♦Vertical Alignment at Railroad Crossings
    • ♦Vertical Alignment at Intersections
    • ♦Vertical Clearance
    • ♦Combination of Vertical and Horizontal Alignment
  • ►7. Cross-Sectional Elements
    • ♦Overview
    • ♦Pavement Cross Slope
    • ♦Median Design
    • ♦Lane Widths
    • ♦Shoulder Widths
    • ♦Pavement Taper Lengths
    • ♦Curb and Curb with Gutters
    • ♦Roadside Design
    • ♦Slopes and Ditches
    • ♦Lateral Offset to Obstructions
    • ♦Clear Zone
  • ►8. Drainage Facility Placement
    • ♦Overview
    • ♦Introduction
    • ♦Design Treatment of Cross Drainage Culvert Ends
    • ♦Parallel Drainage Culverts
    • ♦Side Ditches
  • ♦9. Roadways Intersecting Department Projects
• ►3. New Location and Reconstruction (4R) Design Criteria
  • ►1. Overview
    • ♦Introduction
  • ►2. Urban Streets
    • ♦Overview
    • ♦Level of Service
    • ♦Basic Design Features
    • ♦Medians
    • ♦Median Openings
    • ♦Clear Zones
    • ♦Borders
    • ♦Berms
    • ♦Grade Separations and Interchanges
    • ♦Right-of-Way Width
    • ♦Intersections
    • ♦Speed Change Lanes
    • ♦Drainage Horizontal Offsets
    • ►Bus Facilities
    • ♦Bus Streets
  • ►3. Suburban Roadways
    • ♦Overview
    • ♦Basic Design Features
    • ♦Access Control
    • ♦Medians
    • ♦Median Openings
    • ♦Clear Zones
    • ♦Borders
    • ♦Grade Separations and Interchanges
    • ♦Right-of-Way Width
    • ♦Intersections
    • ♦Speed Change Lanes
    • ♦Parking
  • ►4. Two-Lane Rural Highways
    • ♦Overview
    • ♦Basic Design Features
    • ♦Access Control
    • ♦Transitions to Four-Lane Divided Highways
    • ♦Passing Sight Distances
    • ♦Speed Change Lanes
    • ♦Grade Separations and Interchanges
    • ♦Intersections
  • ►5. Multi-Lane Rural Highways
    • ♦Overview
    • ♦Basic Design Features
    • ♦Level of Service
    • ♦Basic Design Features
    • ♦Access Control
    • ♦Medians
    • ♦Turn Lanes
    • ♦Travel Lanes and Shoulders
    • ♦Intersections
    • ♦Transitions to Four-Lane Divided Highways
    • ♦Converting Existing Two-Lane Roadways to Four-Lane Divided Facilities
    • ♦Grade Separations and Interchanges
  • ►6. Freeways
    • ♦Overview
    • ♦Basic Design Criteria
    • ♦Access Control
    • ♦General
    • ♦Mainlane Access
    • ♦Frontage Road Access
    • ♦Control of Access Methods
    • ♦Control of Access by Design
    • ♦Mainlanes
    • ♦Design Speed
    • ♦Level of Service
    • ♦Lane Width and Number
    • ♦Shoulders
    • ♦Medians
    • ♦Outer Separation
    • ♦Crossing Facilities
    • ♦Vertical and Clear Zones at Structures
    • ♦Frontage Roads
    • ♦Function and Uses
    • ♦Planning
    • ♦Design Speed on Frontage Roads
    • ♦Capacity and Level of Service
    • ♦Frontage Road Design Criteria
    • ♦Conversion of Frontage Roads from Two-Way to One-Way Operation
    • ♦Grade Separations and Interchanges
    • ♦Three-Leg Interchanges
    • ♦Four-Leg Interchanges
    • ♦Diamond Interchanges
    • ♦Cloverleaf Interchanges
    • ♦Directional Interchanges.
    • ♦Interchange Spacing
    • ♦Auxiliary Lanes
    • ♦Ramps and Direct Connectors
    • ♦General Information
    • ♦Design Speed
    • ♦Ramp Geometrics
    • ♦Gores
    • ♦Cross Section and Cross Slopes
    • ♦Sight Distance
    • ♦Ramp Terminal Design
    • ♦Exit Ramps to Frontage Roads
    • ♦Ramp Spacing
    • ♦Metered Ramps
    • ♦Collector-Distributor Roads
    • ♦Frontage Road Turnarounds and Intersection Approaches
  • ►7. Freeway Corridor Enhancements
    • ♦Overview
    • ♦Freeways with High Occupancy Vehicle Treatments
    • ♦Light Rail Transit
    • ♦Peak Hour Lanes
    • ♦Tolled Express Lanes
  • ►8. Texas Highway Freight Network (THFN)
    • ♦Overview
    • ♦Vertical Clearance at Structures
    • ♦Signs, Overhead Sign Bridges (OSB’s), Signals
    • ♦Other Overhead Utilities
• ►4. Non-Freeway Rehabilitation (3R) Design Criteria
  • ►1. Purpose
    • ♦Overview
    • ♦Design Guidelines
  • ►2. Design Characteristics
    • ♦Pavement Design
    • ♦Geometric Design
    • ♦Design Values
    • ♦Alignment
    • ♦Design Speed
    • ♦Side and Backslopes
    • ♦Lane Widths
  • ►3. Designing for Safety
    • ♦Overview
    • ♦Safety Design
    • ♦Basic Safety Improvements
    • ♦Other Safety Improvements
  • ►4. Frontage Roads
    • ♦Overview
  • ►5. Bridges, Including Bridge-Classification Culverts
    • ♦Overview
  • ►6. Super 2 Highways
    • ♦Overview
    • ♦Basic Design Criteria
  • ►7. 3R Project Documentation
    • ♦Project-Specific Design Information
    • ♦Plan Set Requirements
• ►5. Non-Freeway Resurfacing or Restoration Projects (2R)
  • ►1. Criteria
    • ♦Overview
    • ♦Definition
    • ♦Upgrading
    • ♦Crash Analysis
• ►6. Special Facilities
  • ►1. Off-System Bridge Replacement and Rehabilitation Projects
    • ♦Overview
    • ♦Design Values
  • ►2. Historically Significant Bridge Projects
    • ♦Reference for Procedures
  • ►3. Texas Parks and Wildlife Department (Park Road (PR) and Park and Wildlife Road (PW)) Projects
    • ♦Working Agreements
  • ►4. Bicycle Facilities
    • ♦6.4.1 General
    • ♦6.4.2 Planning and Context
    • ♦6.4.3 Elements of Design
    • ♦6.4.4 Bikeway Types
    • ♦6.4.5 Intersections and Crossings
    • ♦6.4.6 Maintenance, Operations, and Work Zone
    • ♦6.4.7. References
• ►7. Miscellaneous Design Elements
  • ►1. Longitudinal Barriers and Roadside Safety Hardware Criteria
    • ♦Overview
    • ♦Concrete Barriers (Median and Roadside)
    • ♦Guardrail
    • ♦Attenuators (Crash Cushions)
    • ♦Roadside Safety Hardware Crash Criteria
  • ►2. Fencing
    • ♦Overview
    • ♦Right-of-way
    • ♦Control of Access Fencing on Freeways
  • ►3. Pedestrian Facilities
    • ♦7.3.1 General
    • ♦7.3.2 Elements of Design
    • ♦7.3.3 Linear Pedestrian Facilities
    • ♦7.3.4 Curb Ramp Design
    • ♦7.3.5 Driveway Design Considerations
    • ♦7.3.6 Intersections and Crossings
    • ♦7.3.7 Overcrossings and Underpasses
    • ♦7.3.8 Work Zone and Temporary Traffic Control Pedestrian Accommodations
    • ♦7.3.9 Lighting
    • ♦7.3.10 On-Street Parking
    • ♦7.3.11 Transit Access
    • ♦7.3.12 Railings Adjacent to Steep Slopes
    • ♦7.3.13 Additional Considerations
    • ♦7.3.14 Micromobility Vehicles
  • ►4. Parking
    • ♦Overview
    • ♦Fringe Parking Lots
    • ♦Parking Along Highways and Arterial Streets
  • ►5. Rumble Strips
    • ♦Overview
    • ♦Considerations for Centerline and Shoulder Rumble Strip Placement
    • ♦Bicyclists Considerations
  • ►6. Emergency Crossovers
    • ♦Overview
    • ♦Location
    • ♦Construction
  • ►7. Minimum Designs for Truck and Bus Turns
    • ♦Overview
    • ♦Application
    • ♦Channelization
    • ♦Alternatives to Simple Curvature
    • ♦Urban Intersections
    • ♦Rural Intersections
    • ♦Median U-Turn Movements
• ►8. Mobility Corridor (5 R) Design Criteria
  • ►1. Overview
    • ♦Introduction
  • ►2. Roadway Design Criteria
    • ♦Overview
    • ♦Lane Width and Number
    • ♦Shoulders
    • ♦Pavement Cross Slope
    • ♦Vertical Clearances at Structures
    • ♦Stopping Sight Distance
    • ♦Grades
    • ♦Horizontal Alignment
    • ♦Superelevation
    • ♦Superelevation Transition
    • ♦Vertical Curves
  • ►3. Roadside Design Criteria
    • ♦Clear Zone
    • ♦Slopes
    • ♦Medians
  • ►4. Ramps and Direct Connectors
    • ♦Overview
    • ♦Design Speed
    • ♦Lane and Shoulder Widths
    • ♦Acceleration and Deceleration Lengths
    • ♦Distance Between Successive Ramps
    • ♦Grades and Profiles
    • ♦Cross Section and Cross Slopes
• ▼A. Longitudinal Barriers
  • ►1. Overview
    • ♦Introduction
  • ▼2. Barrier Need
    • ♦Overview
    • ♦Types of Barrier
    • ♦Applications
    • ♦Working Width
  • ►3. Structural Considerations of Guard Fence
    • ♦Overview
    • ♦Post Spacing, Embedment, and Lateral Support
    • ♦Rail Element
    • ♦Blockouts
  • ►4. Placement of Guard Fence
    • ♦Overview
    • ♦Lateral Placement at Shoulder Edge or Curb Face
    • ♦Lateral Placement Away from the Shoulder Edge
    • ♦Deflection Considerations
  • ►5. End Treatment of Guard Fence
    • ♦Overview
  • ►6. Determining Length of Need of Barrier
    • ♦Overview
    • ♦Variables
    • ♦Design Equations
    • ♦Using Design Equations to Determine Length of Guard Fence
  • ►7. Example Problems
    • ♦Example Problem 1
    • ♦Example Problem 2
    • ♦Example Problem 3
  • ►8. Median Barrier
    • ♦Overview
    • ♦Application
    • ♦Placement
    • ♦Additional Cable Median Barrier Guidance
  • ►9. Emergency Crossovers
    • ♦Overview
    • ♦Location
    • ♦Construction
• ►B. Treatment of Pavement Drop-offs in Work Zones
  • ►1. Overview
    • ♦Scope
    • ♦Types of Treatment
    • ♦Factors Affecting Treatment Choice
    • ♦Edge Condition
    • ♦Guidelines for Treatment
• ►C. Driveway Design Guidelines
  • ♦1. Overview
  • ►2. Introduction
    • ♦General Guidelines
    • ♦Definitions
  • ►3. Driveway Design Principles
    • ♦General Guidelines
    • ♦Geometrics for Two-Way Driveways
    • ♦Divided Driveways
  • ►4. Profiles
    • ♦Driveway Grades
    • ♦Profiles on Curb and Gutter Sections
    • ♦Profiles with Drainage Ditch
  • ►5. Driveway Angle
    • ♦Two-Way Driveways
    • ♦One-Way Driveways
  • ►6. Bicycle and Pedestrian Considerations
    • ♦General Guidelines
  • ♦7. Visibility
  • ♦8. References
• ►D. Right-Turn Slip Lane Design Guidelines
  • ♦1. Introduction
  • ►2. New Construction
    • ♦Urban Design
    • ♦Suburban Design
    • ♦Rural Design
  • ►3. Retrofitting Treatments
    • ♦Providing Proper Refuge for Pedestrians
    • ♦Stopping and Yielding to Crossing Pedestrians
    • ♦Crosswalk Location
    • ♦Reducing Speeds in the Channelized Roadway
    • ♦Enhancing Visibility of Crossing Pedestrians
    • ♦Reducing Head Turning to Spot Oncoming Traffic
    • ♦Slip Lane Removal
  • ♦4. References
• ►E. Alternative Intersections and Interchanges
  • ►1. Overview
    • ♦Introduction: Alternative Intersections and Interchanges
    • ♦Pedestrian Considerations for Alternative Intersections
  • ►2. Roundabouts
    • ♦Overview
    • ♦Planning
    • ♦Geometric Design
    • ♦Entry Width
    • ♦Circulatory Roadway Width
    • ♦Entry Curve
    • ♦Exit Curve
    • ♦Roundabout Speeds
    • ♦Vertical Geometry
    • ♦Cross-Slope
    • ♦Splitter Islands
    • ♦Pedestrian Considerations
    • ♦Bicyclist Considerations
    • ♦Access Management
  • ►3. Diverging Diamond Interchange (DDI)
    • ♦Overview
    • ♦Design Considerations
    • ♦Sight Distance
    • ♦Horizontal Alignment Alternatives
    • ♦Auxiliary Lanes
    • ♦Pedestrian and Bicyclist Considerations
    • ♦Access Management
  • ►4. Median U-Turn Intersection (MUT)
    • ♦Overview
    • ♦Design Considerations
    • ♦Location Considerations
    • ♦Pedestrian and Bicyclist Considerations
    • ♦Access Management
  • ►5. Restricted Crossing U-Turn Intersection (RCUT)
    • ♦Overview
    • ♦Design Considerations
    • ♦Intersection Angle
    • ♦Pedestrian and Bicyclist Considerations
    • ♦Access Management
  • ►6. Displaced Left Turn Intersection (DLT)
    • ♦Overview
    • ♦Design Considerations
    • ♦Sight Distance
    • ♦Pedestrian and Bicyclist Considerations
    • ♦Access Management
  • ♦7. References

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Section 2: Barrier Need

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Overview

Traffic barriers are considered only when the obstacle is less forgiving than striking the barrier itself.

Should a roadside obstacle exist, treatment should be considered in the following priority:

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1. Remove obstacle.
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2. Redesign the obstacle so it can be safely traversed.
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3. Relocate the obstacle to a point where it is less likely to be struck.
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4. Reduce impact severity by using an appropriate breakaway device.
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5. Shield the obstacle with a longitudinal traffic barrier designed for redirection or use a crash cushion.
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6. Delineate the obstacle if the above alternatives are not appropriate.

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Types of Barrier

Rigid

Common rigid barriers used by TxDOT are constant single-slope barriers and F-shape barriers that are cast in place or precast. Concrete barriers placed in situ or keyed into the roadway pavement are considered rigid barriers. Concrete barriers are placed primarily where little movement of the barrier can be tolerated and typically do not deform when impacted. For concrete barriers that are anchored, between 0 and 1-ft of deflection is anticipated for a TL-3 (high-speed) pickup truck impact. Where considerable truck traffic exists or is anticipated, a TL-4 rated barrier should be considered. (Minimum height of a TL-4 barrier is 36 inches). Concrete barriers are typically used at narrow medians. The exposed ends of the barrier need to be protected by an attenuator.

Semi-Rigid

Semi-rigid barriers commonly used by TxDOT include metal beam guard fence and both pinned and unanchored precast concrete barriers. Semi-rigid barriers have an expected deflection between 26 and 60 inches if impacted by a MASH TL-3 pickup truck under MASH test conditions. Metal beam guard fence is the most commonly used barrier by TxDOT. The current height tolerance for a new installation of a (MGS) system is 31 inches plus or minus 1 inch measured from the road surface to the top of w-beam rail. Metal beam guard fence is used primarily to shield roadside obstacles, such as slopes, utility poles, or trees. Precast concrete barriers can be used for temporary or permanent installations. Precast concrete barrier is most commonly used in work zones to shield personnel from traffic.

Flexible

High-tension cable barriers are the most commonly used flexible barriers. A cable barrier is sometimes referred to as a wire rope safety barrier. It consists of high-tension steel cables mounted on weak posts with a post foundation and typical anchor terminal. Cable barriers are used as median barriers to reduce median crossover vehicle encroachments.

Additional guidance for each barrier type is provided in subsequent sections.

Barrier Transitions

When transitioning from one type of barrier to another with significant differences in deflection or working width it is necessary to provide a transition between the two barrier types to gradually increase stiffness to reduce the risk of pocketing and/or snagging. TxDOT has several standards for transitions from Rigid to Semi-rigid (metal beam guard fence) barriers available on the Design Division Roadway standards webpage. The purpose of all these transitions is to gradually decrease the expected deflection to safely redirect an errant vehicle.

Special Barrier Applications

In the application of traffic control plans, situations may arise where transitions are needed from a concrete barrier that has less anticipated deflection to barriers where more deflection is anticipated. The continuum for deflection from less deflection to greater deflection is cast-in-place, precast pinned, and precast non-pinned respectively. Additionally, a temporary barrier run of 120-ft or less would generally be considered a short run and greater deflection would be anticipated. See the Guidebook for Use of Pinned-Down Temporary Concrete Barriers in Limited Space Applications - Roadside Safety Pooled Fund (2016) for additional guidance, or contact the Roadway Design Section of Design Division.

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Applications

The three basic types of obstacles that are commonly shielded using roadside barriers are as follows:

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• Slopes, lateral drop-offs, or terrain features;
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• Bridge ends and the areas alongside bridges; and
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• Other roadside obstacles that cannot be eliminated, made breakaway or otherwise traversable, or relocated.

Table A-1 shows a summary of roadside features that are commonly shielded with guard fence. The abbreviation cz means within clear zone.

Anchor: #CHDDEJIDTable A-1: General Applications of Conditions for Roadside Barriers

Roadside Feature	Applications
Terrain Features: Steep Embankment Slope Rough Rock Cut Boulders Water Body (e.g. Ponds, Detention/Retention Ponds, Lakes, and Rivers/Streams) Lateral Drop-off (e.g. Borrow Pits) Side Ditches	cz1, See Figure A-1 cz cz, diameter exceeds 6-in cz, depth exceeds 2-ft, permanent cz & steeper than 1V:1H and depth exceeds 2-ft cz & unsafe cross section2
Bridges: Parapet Wall/Wingwall/Bridge Rail End Area Alongside Bridges	approaching traffic, or within cz of opposing traffic approaching traffic, or within cz of opposing traffic
Roadside Obstacles: Trees Culvert Headwall3 Wood Poles, Posts Bridge Piers, Abutments at Underpasses Retaining Walls, Noise Wall	cz & diameter exceeds 4-in cz & size of opening exceeds 3-ft (without safety grates only) cz & cross section/area exceeds 50 in2 cz cz & not parallel to travelway
Notes: cz – Within clear zone for highway class and traffic volume conditions. For preferred ditch cross sections, see Chapter 2 Section 8, Side Ditches. For specific 4R requirements see Chapter 2 Section 7, Cross Sectional Elements; for 3R see Chapter 4 Section 3, Designing for Safety.

When evaluating roadside design, consideration should be given to the possible removal of metal beam guard fence if it is no longer needed; providing cross sections that make metal beam guard fence unnecessary is desirable. This includes providing a sufficient clear zone recovery area and re-grading ditches to the extent possible in lieu of metal beam guard fence.

Gateway Monuments are considered discretionary items which means they are not necessary for the safety, maintenance, and operation of the roadway. Gateway Monuments, their foundations and any of their associated appurtenances proposed on the roadside of a facility must not be positioned within the clear recovery zone, and it is desirable that any monuments, their foundations and associated appurtenances be placed at least 10-ft beyond the clear zone. If this cannot be achieved, if a more desirable alternative location is not available, and if the monument must be placed within the clear zone, it must be shielded with an appropriate crashworthy device consistent with TxDOT Roadway standards and applications.

The combination of embankment height and side slope rate may indicate barrier protection consideration as shown in Figure A-1. For low fill heights, a more abrupt slope rate is tolerable than at high fill heights. Because steeper than 1V:4H side slopes provide little opportunity for drivers to redirect vehicles at high speeds, in the absence of guard fence, a 10-ft area free of obstructions should be provided by the designer beyond the toe of slope for steeper slopes.

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Figure A-1. Guide for Use of Guard Fence for Embankment Heights and Slopes

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Working Width

Working width is the distance between the traffic face of the barrier before the impact and the maximum lateral position of any major part of the system or vehicle after the impact. (see Figure A-2). Working width is related to deflection, but working width takes into account the lateral position of the vehicle. Working width should be considered when placing any longitudinal barrier.

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Figure A-2. Working Width