Using Telematics Data Effectively · • Data was collected from Class 1-8 trucks in seven...
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November 27, 2017 Roosevelt C. Mosley, FCAS, MAAA, CSPA Chris Carver Yiem Sunbhanich Using Telematics Data Effectively The Nature Of Commercial Fleets
Transcript of Using Telematics Data Effectively · • Data was collected from Class 1-8 trucks in seven...
November 27, 2017
Roosevelt C. Mosley, FCAS, MAAA, CSPAChris Carver
Yiem Sunbhanich
Using Telematics Data EffectivelyThe Nature Of Commercial Fleets
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About the Presenters
• Roosevelt Mosley, FCAS, MAAA, CSPA• Pinnacle Actuarial Resources, Inc.• Principal and Consulting Actuary
• Chris Carver• SpeedGauge
• Yiem Sunbhanich• TNEDICCA®
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We’re PAST the tipping point. Telematics, mobile phones, tablets, ELDs and/or cameras are present in 58% of fleet vehicles! Those who are not leveraging this data will soon realize they are being adversely selected.
Who?This is not just a session about big trucks! A fleet is any business with 5 or more vehicles.
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• PL telematics provide a selection benefit for very homogeneous risks.
• Commercial Lines include a very heterogeneous mix of vehicles and drivers within a single business class.
• Fleet data has exposed the weakness of zone rating heavy vehicles and territory rating light vehicles.
• Driver turnover is up 270%.• 14% of vehicles are becoming
significantly safer every year, but repair costs on replacement vehicles are up 42%.
• We’re not mandating essential ADAS technologies, even though they yield a 61% reduction in frequency.
The Problem
Heterogeneous vs Homogeneous Mix
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• The current hard market fuels specialty underwriting, but is fully underwriting everything our new reality?
• We should be looking for higher pass rates based on deep insights and fewer errors!
• Innovate with the self-equipped fleets: >58% have data and 73% are willing to share the data.
• Move away from unit rating/experience rating toward exposure rating.
• Rate the actual vehicle and the driver separately.• Require an updated driver list quarterly.
What’s the Solution?
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Comparing different weight vehicles is difficult. Context adds more lift than traditional UBI.
Lift From Context
Relativity
Low Frequency HighExample data for 160K vehicles
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Why Two Scores?
Driver ScoreDriver score describes the real choices a driver makes every day.
Vehicle ScoreFAIR Score®, a proprietary exposure index, tells us about the context of the driven risk by VIN.
For Commercial Lines, do not accept a single variable as descriptive of the driven exposure. People and vehicles change!
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0%
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Exposure by Primary Rating Variable
ISO Rated Actual
• Vehicle Scores, combined with detailed driving data, produce a selection benefit 8.5 times more predictive than territory rating.
• Errors in exposure distribution create large rating errors for fleet vehicles, thus creating residual risk.
Misclassification Creates Residual Risk
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Measuring speeding and braking alone only provides a self-selection benefit!
0.690.84
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Liability Claims
BI PD
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Physical Damage Claims
Collision OTC
Residual Risk Captured Through Context
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• Data was collected from Class 1-8 trucks in seven different programs (included loss sensitive and guaranteed cost clients).
• Geographic area included the lower 48 states.
• All vehicles used telematics.
• Data was normalized by platform and vehicle weight.
• Exposure is based on time on each road segment, not miles.
Building a Contextual Risk Score
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Actual Events versus Premium Relativity
Vehicle Count Collisions Pure Premium Relativity
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External Context: Location Risk
Source: Analysis from TNEDICCA®
Before During
Construction of the turn lane addition
After
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Road Modification Effect Example 1: Adding a Turn Lane
After adding the turn lane, did the drivers who usually frequented this location become “safer drivers”?
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After adding the turn lane, did the drivers who usually frequented this location become “worse drivers”?
External Context: Location Risk
Source: Analysis from TNEDICCA®
Before During
Roundabout Construction
After
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Road Modification Effect Example 2: New Roundabout
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Source: Analysis from TNEDICCA®
Crash Locations Matter
Process design drives outcomes more than an individual’s behavior. Most traffic crashes consistently occur within a limited set of locations.
90%
34%
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66%
Proportion ofLocations
Contribution of TotalCrashes
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From Location Risk to Contextual Risk Score
Demo:https://www.youtube.com/watch?v=2iJmRqB7pco&feature=youtu.be
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• Telematics data
• No associated loss experience
None
• Telematics data
• Historical loss experience
Historical Experience
• Telematics data
• Loss cost experience from the same period
Concurrent Experience
UBI Score Analysis – Steps to Contextual Analysis
• Mileage
Trip Summary Information
• Hard braking
• Harsh acceleration
• Speeding
Indicators
• Internal context
• External context
Contextual Information
Analysis Data
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Putting Telematics Data into Context
Should these trips be evaluated differently?
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• Heading
• Change in heading (prior 4 readings)
• Speed
• Change in speed (prior 4 readings)
• Feet per second
• Change in feet per second
• Speed limit
• Speed – speed limit
• Speeding indicators (0, 5 and 10 mile buffers)
• Road class
• Hour
Data Used for UBI Scoring Analysis
• 59,000 unique trips (new trip starts when a vehicle is at rest for 60 or more minutes)
• 2.7 million miles
• Trip length average: 2 hours and 15 minutes
• Average distance traveled per trip: 45 miles
• Average mileage per day: 123
Data Elements Summary Statistics
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Speed
Speed
Speed
• In general, higher speed translates into a worse driving evaluation.
• Many plans use a single speed cut-off.
• In this example, a cut-off of 70 miles or hour results in 3.6% of the readings having a negative evaluation.
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077%
123%
Speed Above Limit
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Speed Above Limit
• Indicator = 1 for readings where speed is greater than speed limit
• Begins to add some context to the raw speed measure
• Still does not tell the entire story
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Speed Minus Speed Limit
Speed Minus Speed Limit
Speed Minus Speed Limit
• Calculation of speed minus speed limit
• Provides additional context and risk segmentation –takes a single indicator and provides additional segmentation of the risk
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Change in Feet per Second
Change in Feet Per Second
Adding Historical Context – Change in Feet per Second
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• Traditional Analysis
– Count of braking, speeding, acceleration
– Application of research studies to traditional data
• Clustering/Segmentation
– Unsupervised classification technique
– Groups data into set of discrete clusters or contiguous groups of cases
– Performs disjoint cluster analysis on the basis of Euclidean distances computed from one or more quantitative input variables and cluster seeds
– Data points are grouped based on the distances from the seed values
– Objects in each cluster tend to be similar, objects in different clusters tend to be dissimilar
• Benefit – telematics readings classified based on entire record, not just value of one element
Clustering/Segmentation
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Cluster Distances
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• Average change in feet per second (t – 1 to t – 2) = 156
• Average change in feet per second (t – 2 to t – 3) = -55
Cluster 2 Description
Element Cluster 17 Overall Average
Highway Road Class 45.7% 15.1%
Time of Day: 12 – 5 am 0.8% 0.4%
Time of Day: 7 – 8 am 1.0% 0.6%
Time of Day: 5 – 9 pm 10.5% 9.0%
Time of Day: 9pm – 12 am 2.2% 1.4%
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Distance from Cluster Mean
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Distance from Cluster Mean
Distance from Cluster Mean
Series1 Speeding
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Number of Different Clusters Assigned to Each Trip
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Number of Behavior Clusters Assigned to Trip
Number of Behavior Clusters Assigned to Trip
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• Telematics data isn’t the only way to achieve pricing precision, but it helps!
• Ignoring telematics data limits pricing innovation.
• Much of the premium leakage comes from the what, by whom and how much a vehicle drives.
• Rate each vehicle, and you’ll discover at least 6% of rate.
• Knowing what’s happening on the road ahead is going to prepare you for the future.
Summary
11/27/20
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The road ahead is clear, despite the picture in the rearview mirror:
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Questions
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Join Us for the Next APEX Webinar
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• We’d like your feedback and suggestions
• Please complete our survey
• For copies of this APEX presentation
• Visit the Resource Knowledge Center at Pinnacleactuaries.com
Final Notes
30Commitment Beyond Numbers
Thank You for Your Time and Attention
Roosevelt Mosley
Chris Carver
Yiem Sunbhanich
