Event data recorder


An event data recorder, similar to an accident data recorder sometimes referred to informally as an automotive "black box", is a device installed in some automobiles to record information related to vehicle crashes or accidents. In the USA EDRs must meet federal standards, as described within the U.S. Code of Federal Regulations.
The black box of in-vehicle data recorders terms are larger as they can refer to EDR or to Journey data recorders such as Digital tachograph in Europe or Electronic logging device in the USA.
In modern diesel trucks, EDRs are triggered by electronically sensed problems in the engine, or a sudden change in wheel speed. One or more of these conditions may occur because of an accident. Information from these devices can be collected after a crash and analyzed to help determine what the vehicles were doing before, during and after the crash or event. The term generally refers to a simple, tamper-proof, read-write memory device.

History

Since between 2006 and 2012, the US has fitted vehicles with event data recorders, according to american regulation 49 CFR 563.
Since between 2008 and 2019, Korea has fitted vehicles with event data recorders, according to Korean regulation KMVSS Art. 56-2.
Since between 2008 and 2015, Japan has fitted vehicles with event data recorders, according to japanese regulation J-EDR, for passenger cars.
Since between 2012 and 2015 Switzerland has fitted vehicles with event data recorders, according to regulation VTS Art. 102, applicable to vehicles with blue lights and sirens.
Since between 2003 and 2005, Uruguay has fitted vehicles with event data recorders, according to Decree 560/003 Art. 11, for dangerous goods vehicles.
China has drafted a regulation which would become mandatory for all passenger cars as of January 2021.

Regulatory framework

In the US 49/563.5 regulatory framework, Event data recorder is defined as a
In an EU parliament text adopted in 2019, event data recorder requirements assume:

Operation

Some EDRs continuously record data, overwriting the previous few minutes until a crash stops them, and others are activated by crash-like events and may continue to record until the accident is over, or until the recording time is expired. EDRs may record a wide range of data elements, potentially including whether the brakes were applied, the speed at the time of impact, the steering angle, and whether seat belt circuits were shown as "Buckled" or "Unbuckled" at the time of the crash. Current EDRs store the information internally on an EEPROM until recovered from the module. Some vehicles have communications systems that may transmit some data, such as an alert that the airbags have been deployed, to a remote location.
Most EDRs in automobiles and light trucks are part of the restraint system control module, which senses impact accelerations and determines what restraints to deploy. After the deployment decisions are made, and if there is still power available, the data are written to memory. The data downloaded from older EDRs usually contain 6 to 8 pages of information, though many newer systems include many more data elements and require more pages, depending on the make/model/year of the vehicle being evaluated. Depending on the type of EDR, it may contain either a deployment file or a non-deployment file or sometimes both, depending on the circumstances of the collisions and the time interval between them, among other things.
It is also possible that no data can be recovered from a data recorder. One situation where this might occur is a catastrophic loss of electrical power early in a collision event. In this situation, the power reserve in the restraint system control module capacitors may be completely spent by the deployment of the air bags, leaving insufficient power to write data to the EEPROM. There are other circumstances where a module may fail to record a data file as well.
Most EDRs in heavy trucks are part of the engine electronic control module, which controls fuel injection timing and other functions in modern heavy-duty diesel engines. The EDR functions are different for different engine manufacturers, but most recognize engine events such as sudden stops, low oil pressure, or coolant loss. Detroit Diesel, Caterpillar Inc., Mercedes-Benz, Mack Trucks, and Cummins engines are among those that may contain this function. When a fault-related event occurs, the data is written to memory. When an event triggered by a reduction in wheel speed is sensed, the data that is written to memory can include almost two minutes of data about vehicle speed, brake application, clutch application, and cruise control status. The data can be downloaded later using the computer software and cables for the specific engine involved. These software tools often allow monitoring of the driver hours of service, fuel economy, idle time, average travel speeds, and other information related to the maintenance and operation of the vehicle.
Some EDRs only keep track of the car's speed along its length and not the speed going sideways. Analysts generally look at the momentum, energy, and crush damage, and then compare their speed estimates to the number coming out of the EDR to create a complete view of the accident.
There are many different patents related to various types of EDR features.

Data from the Eaton VORAD Collision Warning System

The Eaton Vehicle Onboard Radar Collision Warning System is used by many commercial trucking firms to aid drivers and improve safety. The system includes forward and side radar sensors to detect the presence, proximity and movements of vehicles around the truck to then alert the truck driver. When sensors determine that the truck is closing on a vehicle ahead too quickly or that a nearby vehicle is potentially hazardous, the VORAD system gives the driver both a visual and audible warning. The VORAD system also monitors various parameters of the truck including vehicle speed and turn rate plus the status of vehicle systems and controls.
The monitored data is captured and recorded by the VORAD system. This monitored data can be extracted and analyzed in the event of an accident. The recorded data can be used by accident investigators and forensic engineers to show the movement and speed of the host vehicle plus the position and speeds of other vehicles prior to the incident. In accident reconstruction, the VORAD system is a step above the EDR systems in that VORAD monitors other vehicles relative to the host vehicle, while EDR’s only record data about the host vehicle.

Usage of event data recorders

Event data recorders were introduced to American open-wheel championship CART in the 1993 season, and the Formula One World Championship in 1997. Data collected by the recorders was used to improve safety and design factors in race vehicles and racetracks.
Usage of the device in road vehicles once varied widely from manufacturer to manufacturer, but EDRs are now mandated in all new vehicles. As of 2004, an estimated 40 million passenger vehicles are equipped with the devices.
In the UK many police and emergency service vehicles are fitted with a more accurate and detailed version that is produced by one of several independent companies. Both the Metropolitan police and the City of London police are long-term users of EDRs and have used the data recovered after an incident to convict both police officers and members of the public.

Accessing event data recorder information

Methods of accessing EDR data

Downloading an airbag module in most vehicles is best accomplished by connecting the appropriate scanning tool to the Diagnostic Link Connector usually found under the vehicle's dashboard near the driver's knees. Alternately, some modules can be downloaded "on the bench" after removal from the vehicle.

The Bosch CDR tool

Over 88% of model year 2016 and newer vehicles are supported by the Bosch CDR tool, enabling the retrieval of Event Data Recorder data from a vehicle that has been involved in a crash. This tool is made up of hardware and software which provides the ability to “image”, “download”, or “retrieve” EDR data that may be stored in the control modules of passenger cars, light trucks and SUVs. The software component is a single, standalone program designed to run in a Windows environment. The hardware part of the Tool is a collection of components including cables and adapters which, with proper training and minimal difficulty, are used to “retrieve” data from supported vehicles.

Subaru, Kia, and Hyundai EDR tools

Another 11% of model year 2016 and newer vehicles are supported by other EDR tools. The limited need to cover less commonly supported vehicles may make the initial investment in software and equipment unnecessary for many in the accident reconstruction or related industries.

NHTSA's Event Data Recorder Ruling

From 1998 to 2001, the National Highway Traffic Safety Administration sponsored a working group specifically tasked with the study of EDRs. After years of evaluation, NHTSA released a formal Notice of Proposed Rulemaking in 2004. This notice declared NHTSA’s intent to standardize EDRs. It was not until August 2006 that NHTSA released its final ruling. The ruling was lengthy, consisting of not only definitions and mandatory EDR standards, but also acted as a formal reply to the dozens of petitions received by NHTSA after the 2004 notice.
Since there was already an overwhelming trend for voluntary EDR installation, the ruling did not require manufacturers to install EDRs in vehicles produced for North America. Based on its analysis, NHTSA estimated that by 2010, over 85% of vehicles would already have EDRs installed in them, but warned that if the trend did not continue, the agency would revisit their decision and possibly make installation a requirement.
The mandate did, however, provide a minimum standard for the type of data that EDRs would be required to record: at least 15 types of crash data. Some of the required crash data include pre-crash speed, engine throttle, brake use, measured changes in forward velocity, driver safety belt use, airbag warning lamp status and airbag deployment times.
In addition to the required data, NHTSA also set standards for 30 other types of data if EDRs were voluntarily configured to record them. For example, if a manufacturer configured an EDR to record engine RPMs or ABS activity, then the EDR would have to record 5 seconds of those pre-crash data in half-second increments.
Besides the requirement that all data be able to survive a 30 MPH barrier crash and be measured with defined precision, NHTSA also required that all manufacturers make their EDR data publicly available. As of October 2009, only General Motors, Ford and Daimler Chrysler had released their EDR data to be publicly read.
In the August 2006 ruling, NHTSA set a time table for all vehicle manufacturers to be in compliance with the new EDR standards. The compliance date was originally set for all vehicles manufactured after September 1, 2010. But in 2008, NHTSA pushed the date back to September 1, 2012. In 2014, it was working on another rule update to give vehicle manufacturers until September 1, 2014, but that rule was never issued.

EDR needs for ADAS

In 2020, an NTSB communication recall that ADAS system could collect information useful for crash analysis and risk assessment, but that federal regulators failed to standardize it.
In the meantime, some regulators consider Event Data Recorder is a feature for conventional vehicle, while and automated vehicle should have Data Storage System for Automated Driving : The EDR aims to analysis accident, while the DSSAD should be used for research, monitoring, liability,
legal responsibility.

Privacy concerns

Despite alerts and warnings in their vehicle owner's manual, many drivers are not aware of their vehicle's recording capability. Civil liberty and privacy groups have raised concerns about the implications of data recorders 'spying' on car users, particularly as the issue of 'who owns the data' has not yet been fully resolved, and there has been some controversy over the use of recorded data as evidence in court cases and for insurance claims against the driver of a crashed vehicle. But the use of EDR data in civil and criminal court cases is on the rise as they become more accepted as a source of reliable empirical evidence in accident reconstruction.
Fourteen states have statutes specific to EDRs. Generally, these state statutes restrict access to the EDR or limit the use of recovered EDR information.
The federal Driver Privacy Act of 2015 was enacted on December 4, 2015. It stated that the owner or lessee of a motor vehicle is the owner of the data collected by the EDR. In order to access that data, an investigator would need to be authorized by a court or judicial or administrative authority, subject to the standards for admission into evidence; obtain the written, electronic or recorded audio consent of the vehicle owner or lessee; be conducting an investigation or inspection authorized by federal law; demonstrate it is necessary to facilitate medical care in response to a car accident; or be conducting traffic safety research, so long as the personal information of the owner/lessee is not disclosed.

Use as evidence in courts

There have been a number of trial cases worldwide involving EDRs. Drivers have been convicted and exonerated as a result of EDR evidence.
Examples include:
Although EDR evidence can be valuable in the litigation of traffic-related accidents and incidents, the primary purpose of an EDR is to improve driver safety and not to provide data for accident reconstruction, and courts should consider the limitations of EDR data in determining the cause of traffic accidents.

Notable

N.J. Governor Jon Corzine

On 12 April 2007, N.J. Governor Jon Corzine was seriously injured in an automobile accident. According to the superintendent of state police, an Event Data Recorder in the SUV he was traveling in recorded he was traveling at about 91 MPH five seconds before the crash. The speed limit on the road is 65 MPH. The Governor was not the driver of the vehicle.

Mass. Lt. Governor Tim Murray

On November 2, 2011, Mass. Lt. Governor Tim Murray crashed a government-owned vehicle on a stretch of Interstate 190. Initially, police investigating did not issue any citations.
Murray initially claimed he simply lost control on the ice, wasn’t speeding, was wearing a seat belt and braked. But those claims were all later disproven when the Crown Victoria black box data recorder information was released. The data revealed the car was traveling 108 miles per hour, accelerated, and the Lt. Governor was not wearing a seat belt at the time the vehicle collided with a rock ledge and flipped over. Murray was unhurt in the accident.

Video Event Data Recorder

A Video Event Data Recorder is a device that records video in a vehicle to create a record of accidents and for evaluating driver and vehicle performance.