Remote Sensing for Asset Management

Remote Sensing for Asset Management Shauna Hallmark Kamesh Mantravadi David Veneziano Reginald Souleyrette September 23, 2001 Madison, WI

The Problem/Opportunity • DOT use of spatial data • Planning • Infrastructure Management • Traffic engineering • Safety, many others • Inventory of large systems costly • e.g., 110,000 miles of road in Iowa

The Problem/Opportunity • Current Inventory Collection Methods • Labor intensive • Time consuming • Disruptive • Dangerous

Data Collection Methodologies • Manual (advantages/disadvantages) • low cost • visual inspection of road • accurate distance measurement • workers may be located on-road • difficult to collect spatial (x,y) • Video-log/photolog vans(advantages/disadvantages) • rapid data collection • digital storage • difficult to collect spatial (x,y)

Data Collection Methodologies • GPS (advantages/disadvantages) • highly accurate (x,y,z) • can record elevation • time consuming if high accuracy is required • workers may be located on-road

Data Collection Methodologies • Remote sensing (advantages/disadvantages) • Data collectors not located on-site • Initially costly but multiple uses • Can go back to the images

Research Objective • Can remote sensing be used to collect infrastructure inventory elements? • What accuracy is possible/necessary?

Remote Sensing • "the science of deriving information about an object from measurements made at a distance from the object without making actual contact” Campbell, J. Introduction to Remote Sensing, Second Edition. • Applications in many fields such as forestry, Oceanography, Transportation

Remote Sensing • 3 types 1) space based or satellite • Images acquired from space 2) airplane based or aerial • Images acquired form aerial platforms like high, low altitude airplanes and balloons. (USGS) 3) in-situ or video/magnetic

Research Approach • Identify common inventory features • Identify existing data collection methods • Use aerial photos to extract inventory features • Performance measures • Define resolution requirements • Recommendations

Application • Use of Remote sensing to collect features for the Iowa DOT’s Linear Referencing System (LRS) • Datum • Anchor points • Anchor sections • Business data • Inventory features

Datum • Anchor points • Physical entity • (X,Y) • Intersection of 2 roadways • Intersection of RR and roadway • Edge of median • Bridges • Anchor sections • Measurement of distance between anchor points along roadway Anchor point Anchor section

Datum Accuracy Requirements • Anchor points • ± 1.0 meter • Anchors sections • ± 2.1 meter

Common Business Data Items • Shoulder Type • Shoulder Width • Right and Left • Number of Right/Left Turn Lanes • Number of Signalized Intersections • Number of Stop controlled Intersections • Number of Other Intersections • HPMS requirements • Additional Iowa DOT elements • Section Length • Number of Through Lanes • Surface/Pavement Type • Lane Width • Access Control • Median Type • Median Width • Parking

Imagery Datasets • 2-inch dataset - Georeferenced • 6-inch dataset - Orthorectified • 2-foot dataset – Orthorectified • 1-meter dataset – Orthorectified – simulated 1-m Ikonos Satellite Imagery * not collected concurrently

Performance Measures • Establishing geographic location of anchor points and business data • Positional accuracy • Variation between operators for locating elements (Operator Variability) • Ability to recognize features in imagery (Feature Recognition) • Calculation of anchor section lengths • Establishing roadway centerline

Positional Accuracy • Root Mean Square (RMS) • Imagery position vs. position w/ GPS (centimeter horizontal accuracy) • 2 easily identified features selected • Could be identified in all 4 datasets • Had a distinct point to locate SE corner of intersecting sidewalks SE corner of drainage structure

Positional Accuracy • 2-inch, 6-inch, 24-inch met accuracy requirements of Iowa DOT LRS for anchor points • Even for 1-meter RMS < 2 meters • 95% of points were located within < 3.5 meters for all datasets --- sufficient accuracy for most asset management applications

Operator Variability • For manual location of features • How much of spatial error can be attributed to differences in how data collectors locate objects Variation among observers in spatially locating a point

Operator Variability Edge of drainage structure as located by 7 operators • 7 operators located 8 sets of features • Traffic signal posts • Drainage structures • Pedestrian crossings • Center of intersections • Center of driveways • RR crossings • Bridges • Medians • Specific instructions for locating (i.e. SE corner of bridge) • Compared variability among observers

Operator Variability (results) • Only 3 features could be identified consistently in all 4 datasets • Driveways --- RR Crossings • Center of intersections • 5 other features identified in 6-inch & 2-inch datasets

Operator Variability (results) • Certain features, such as railroad crossings, could be located with less variation than features such as driveway centers (less distinct) • mean variability < 0.5 meters • Drainage structures, driveways, traffic signal posts, pedestrian crossings (2 and 6-inch tested only) • mean variability >= 0.5 m & < 1.0 m • Medians (2 & 6-inch tested only, RR crossings) • mean variability >= 1.0 m • Intersections, bridges • Significant variability in features used as anchor points • Variability ~ allowed error (1.0 meter)

Feature Identification • Points can be located within allowance for anchor points (± 1.0 m) for all but 1-meter • Even 1-meter rms < 2.0 meters, sufficient for most asset-related applications • But can features be consistently recognized IP (%) = (Fa/Fg) * 100 • % of features recognized in imagery compared to ground count Extraction of features from 6-inch image

Feature Identification

Feature Identification • Of 21 features • 2-inch: 100% identified consistently • 6-inch: > 80% identified consistently • Signs, median type, stopbars, utility poles • 24-inch: < 50% consistently identified • 6 features not identified at all • 1-meter: < 25% consistently identified • 8 features not identified at all

Calculation of anchor section lengths • Linear measure along roadway centerline between anchor points • Iowa DOT LRS requires ± 2.1 m • Established centerline and measured for 7 test anchor section test segments • Compared against DMI • values from Iowa DOT LRS Pilot Study • Also collected distance using Roadware DMI van (but collected at ± 10 m)

Anchor Section Results • None of the methods met ± 2.1 m RMS required for anchor section distances • **** Iowa DOT study found 6-inch met accuracy requirement *** • All imagery: RMS < 8 meters • All imagery: mean < 2 m

Establishing Roadway Centerline Typical Segment on Dakota (imagery and DGPS) • Compared centerline representation of 3 methods • Imagery • VideoLog DGPS • Roadway DGPS Deviation from datum (m)

Establishing Roadway Centerline Worst Alignment on Union (DGPS) Deviation from datum (m)

DGPS Traces from Iowa DOT LRS Pilot Study Nevada, IA

Conclusions • Most significant issue with imagery • At lower resolutions, difficult to identify features • Spatial accuracy for all imagery datasets comparable • Limiting factor is ability to consistently identify features • Minimum of 6-inch required for identification of features • 1-meter or 24-inch: • for measurement of centerline • Identification of large features

Questions?

Remote Sensing for Asset Management

Remote Sensing for Asset Management

Presentation Transcript

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Remote Asset Management Market

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