Methodology

• Methodology

  • Comparing autonomous vehicle and human performance

    

    

    Despite the public availability of crash data for both human-driven and autonomous vehicles, drawing meaningful comparisons between the two is challenging. To ensure a fair comparison, there’s a number of factors that should be taken into consideration. Here are some of the most important:

    • AV and human data have different definitions of a crash. AV operators like Waymo must report any physical contact that results or allegedly results in any property damage, injury, or fatality, while most human crash data require at least enough damage for the police to file a collision report.
    • Not all human crashes are reported. NHTSA estimates that 60% of property damage crashes and 32% of injury crashes aren’t reported to police (Blincoe et al. 2023). In contrast, AV companies report even the most minor crashes in order to demonstrate the trustworthiness of autonomous driving on public roads.
    • Focus should be put on injury-causing crashes. Low speed crashes that result in minor damage can cause property damage that can be quickly repaired. These low speed crashes are also the most frequent types of crashes. In traffic safety, the most emphasis is put on reducing the highest severity crashes that can result in injuries.
    • It’s important to look at rates of events (incidents per mile) instead of absolute counts. Waymo is growing its operations in the cities we operate in. With more driving miles come more absolute collisions. It’s critical to consider the total miles driven to accurately calculate incident rates. If you do not consider the miles driven, it may appear like incidents are increasing while in reality the rate of incidents could be going down.
    • All streets within a city are not equally challenging. Waymo’s operations have expanded over time, and, because Waymo operates as a ride-hailing service, the driving mix largely reflects user demand. A limitation of these presented benchmarks is that spatial and temporal differences between the Waymo and human benchmarks within these deployed cities have not been accounted for in the rates. It should be noted that Waymo drives more predominantly in the densest parts of these deployed areas where crash rates tend to be higher.

    Waymo has used industry best-practices to make a fair comparison between AV and human data sources that is presented on this webpage. This analysis is described more below, and in even more depth in several of Waymo’s safety publications.

  • How we select Waymo incidents noted in this hub

    

    

    Waymo’s data is derived from crashes reported under NHTSA’s Standing General Order (SGO) and uses the same criteria as described in Kusano et al. (2024).

    We are intentionally using publicly available data to allow other researchers to replicate the results. To link the data shown on this dashboard to NHTSA’s published SGO data, researchers can download a list of SGO report IDs and boolean membership in each outcome group in the download section below.

    We compare Waymo’s crash rate to human benchmarks across several different types of crashes:

    Outcome	Description	Waymo Data*	Human Benchmark
    Police-reported	A crash where a police report is filed	Any SGO reported crash with the field “Law Enforcement Investigating” as “Yes” or “Unknown”.	Police-reported crashed vehicle rate using state crash data. No underreporting adjustment was applied.
    Any-injury-reported	A crash where any road user is injured as a result of the crash	Any SGO reported crash with the field “Highest Injury Severity Alleged” is “Minor” or “Serious” (i.e., excluding “No Injuries Reporting” and “Unknown”).	Police-reported crashed vehicle rate where at least one road user had a reported injury. A 32% underreporting adjustment was applied according to Blincoe et al (2023).
    Airbag deployment	A crash where an airbag deploys in any vehicle	Any SGO reported crash where the “Any Air Bags Deployed?” is “Yes” for either the subject vehicle (SV) or counter party (CP).	Police-reported crashed vehicle rate where any vehicle involved in the crash had an airbag deployment. No underreporting adjustment was applied.

    *Based on initial data submitted as part of the NHTSA Standing General Order 2021-01

  • Human benchmarks

    

    

    The human benchmark data are the same as reported in Scanlon et al. (2024). These benchmarks are derived from state police reported crash records and Vehicle Miles Traveled (VMT) data in the areas Waymo currently operates RO services (Phoenix, San Francisco, and Los Angeles). The human benchmarks were made in a way that only the crashes and VMT corresponding to passenger vehicles traveling on the types of roadways Waymo operates on (excluding freeways).

    It’s worth noting that all streets within a city are not equally challenging. If Waymo drives more frequently in more in challenging parts of the city that have higher crash rates, it may affect crash rates compared to quieter areas. Ideally the human benchmarks should reflect this but that is not always possible. Benchmarks may only be possible at a city level, not for specific streets or areas. The any-injury-reported benchmark also used a 32% underreporting correction (based on NHTSA’s Blincoe et al., 2023 study) to adjust for crashes not reported by humans. The Police-reported and airbag deployment human benchmarks rates used the observed crashes without an underreporting correction.

  • Confidence intervals and data limitations

    

    

    Confidence intervals for Incidents Per Million Miles (IPMM) crash rates were computed using a Poisson Exact method. The confidence intervals for the percent reduction used a Clopper-Pearson binomial described in Nelson (1970). Both confidence intervals were assessed at a 95% confidence level. These confidence intervals use the same methods as described in Kusano et al. (2023).

    There is no perfect “apples-to-apples” comparison between human and AV data available today. The benchmarks and comparisons done on this page represent the current state-of-the-art human and AV data sources, based on the state of the art in the research in this field. The airbag deployment benchmark does not have an underreporting correction for the human data because there is no estimate for airbag crash underreporting. Although, it is likely there is more underreporting in human crash data compared to AV crash data. The any-injury-reported benchmark does use an underreporting correction from Blincoe et al. (2023) based on multiple analyses of national crash police-report and insurance data and a national phone survey. It is not straightforward to compute confidence intervals on the any-injury-reported underreporting estimate because it is derived from multiple sources. There is also evidence that underreporting may differ between localities, meaning a national estimate may not fully represent underreporting in the cities Waymo operates in. Similar to the airbag benchmark, the police-reported benchmark has no underreporting estimate even though it is likely there is more underreporting in human data than the AV data (i.e., a crash that meets the reporting threshold is not reported to police).

    See Scanlon et al. (2024) and Kusano et al. (2024) for a more comprehensive discussion of the limitations of these results:

    1. Scanlon, J. M., Kusano, K. D., Fraade-Blanar, L. A., McMurry, T. L., Chen, Y. H., & Victor, T. (2024). Benchmarks for Retrospective Automated Driving System Crash Rate Analysis Using Police-Reported Crash Data. Traffic Injury Prevention (In Press). DOI:10.1080/15389588.2024.2380522.
    2. Kusano, K. D., Scanlon, J. M., Chen, Y. H., McMurry, T. L., Chen, R., Gode, T., & Victor, T. (2024). Comparison of Waymo Rider-only crash data to human benchmarks at 7.1 million miles. Traffic Injury Prevention (In Press). DOI:10.1080/15389588.2024.2380786.

• FAQ

  • Why is there no local data for Los Angeles and Austin?

    

    

    Waymo has driven limited miles in certain cities compared to others. When there are limited miles, the comparisons are not statistically significant. We are not showing the results for these areas with limited Waymo miles because the confidence intervals are so large that they would distort the axes of graphs shown on this page. We do present the results from all areas we have driven RO miles in the download section.

  • Why does the hub report on airbag deployment, injury-causing, and police-reported crashes?

    

    

    Crashes that have airbag deployments, result in injuries, or are reported to police are more relevant to assessing safety than those that result in small amounts of property damage.

  • How often is the data being updated?

    

    

    In this analysis, we use publicly available data — specifically, Waymo’s crash reports submitted under NHTSA’s Standing General Order (SGO) — to enable other researchers to replicate the results. The data displayed on this webpage undergoes consistent updates aligned with the NHTSA SGO reporting timelines.

  • Has your methodology been peer reviewed or validated externally?

    

    

    This analysis leverages the methodology and human benchmarks introduced in Scanlon et al. (2024) and Kusano et al. (2024).

    Both research papers have been accepted for publication in the Traffic Injury Prevention scientific journal, and we anticipate their publication later this year.

    Citations:

    • Scanlon, J. M., Kusano, K. D., Fraade-Blanar, L. A., McMurry, T. L., Chen, Y. H., & Victor, T. (2024). Benchmarks for Retrospective Automated Driving System Crash Rate Analysis Using Police-Reported Crash Data. Traffic Injury Prevention (In Press). doi:10.1080/15389588.2024.2380522.
    • Kusano, K. D., Scanlon, J. M., Chen, Y. H., McMurry, T. L., Chen, R., Gode, T., & Victor, T. (2024). Comparison of Waymo Rider-only crash data to human benchmarks at 7.1 million miles. Traffic Injury Prevention (In Press). doi:10.1080/15389588.2024.2380786.

  • Why don’t you share fault information for these collisions?

    

    

    This analysis included all collisions, regardless of the party at fault and Waymo’s responsibility. Moreover, the question of fault in causing or contributing to a collision is a legal determination. That said, the recent study led by Swiss Re showed that over 3.8 million miles, the Waymo Driver reduced the frequency of property damage insurance claims by 76% and completely eliminated bodily injury claims compared to human drivers.

  • Does this data mean the Waymo Driver is safer than humans?

    

    

    This analysis shows that the Waymo Driver reduces airbag deployment, injury, and police-reportable crashes compared to human drivers in the cities where it operates. Other studies further support these findings and contribute to the growing evidence of the Waymo Driver’s safety benefits. As we accumulate more mileage, it will become possible to make statistically significant conclusions on other subsets of data (for example, LA, Austin, crash types, and more serious types of crashes).

    There’s no single metric to evaluate the safety of AVs, and an aggregate, retrospective analysis like this may be one important factor in confirming design elements and predictions done in earlier iterations of our safety determination lifecycle.

  • What about Waymo’s impact on fatalities?

    

    

    This analysis reviews all crashes that result in any injury – from minor cases to fatal ones – demonstrating that the Waymo Driver outperforms comparable human benchmarks. The Waymo Driver is also inherently designed to mitigate or eliminate the top causes of fatal collisions according to the latest NHTSA data: speeding, impaired and distracted driving, and unbelted passengers.

    As we accumulate more mileage, it will become possible to make statistically significant conclusions on other subsets of data (for example, LA, Austin, crash types, and more serious types of crashes).

    As has been the case for many safety innovations in the history of vehicle safety, there are other ways to determine the potential of a technology before it is widely deployed and miles are accumulated. For example, our research that reconstructed fatal crashes involving human drivers in Chandler, AZ found the Waymo Driver avoided 100% of simulated, fatal crashes when it was the initiator, and 82% of collisions even when it was the responder. This type of study, when paired with Waymo’s safety readiness determination process, shows that the Waymo Driver has a tremendous potential to reduce serious and fatal injuries.

  • Why does the Waymo SGO data download include crash day, location and zip code?

    

    

    This information is important to analyze and understand collisions and is not available in the NHTSA SGO.