Passenger rail station safety improvement and analysis of end-of-track collisions based on systems-theoretic accident modeling and processes (STAMP)

4.1 Structure of systems-theoretic accident modeling and processes-based accident analysis

In STAMP models, safety (e.g. train operation safety at stub-end passenger stations) is viewed as a control problem. Leveson (2003) summarized that accidents took place owing to an inadequate enforcement of safety-related constraints on the development, design and operation of the system instead of a series of failure events. Three basic concepts in STAMP, namely, the hierarchical level of control, constraints and process models, are briefly introduced in the following.

In system theory, systems are viewed as hierarchical structures, in which each hierarchical level imposes constraints on the activity of the level below it. Constraints or the lack of constraints at a certain level would control or permit lower-level behavior (Checkland, 1981), which includes the engineering design, physical components, management, human factors and regulatory behavior. Components that violate safety-related constraints of the system or their interactions are likely to result in accidents. Taking train operation in the USA as an example, a hierarchical socio-technical control structure combines five socio-technical system levels, namely, the American Congress, governmental agencies (e.g. Federal Railroad Administration (FRA), NTSB), industrial associations (e.g. American Public Transportation Association and Association of American Railroads), railroad companies and operating processes involving train crewmembers as well as train movements from top to bottom in general.

Apart from constraints and hierarchical levels of control, the process model is also a basic concept in STAMP. Figure 1 shows a basic process control loop where a human controller (e.g. a train engineer) takes charge of train operation. In essence, there are two common controllers in the model of a controlled system, namely, the human controller and the automated controller. Based on commonly employed train operation methods in the USA, train movements are primarily controlled and managed by human controllers, which are also supervised by a train protection controller, such as positive train control (PTC). PTC is a train control system capable of a reliable and functional prevention of train accidents attributable to human errors by slowing down or stopping trains automatically. It is indicated that the PTC system is not a completely automated controller everywhere, which, instead, functions and takes charge of train operation only if the human controller (e.g. train engineer) fails to or inadequately controls the train safely and properly, even though PTC keeps monitoring the performance of engineers and train movements. Therefore, in Figure 1, the interconnection between the train control system and the actuator (commands applied by train control system to actuator) is marked with a dashed line, representing that this channel works conditionally and is not always active. Furthermore, since the mandate of the Rail Safety Improvement Act in 2008 (Congress of the United States of America, 2008), a nationwide implementation of PTC has been underway in the USA. Railroads serving for toxic- or poisonous-by-inhalation hazardous materials and those providing a regular intercity or commuter rail passenger transportation were required to implement the PTC system by December 31, 2018, with the opportunity for an additional two years upon the approval from FRA (FRA, 2011; Congress of the United States of America, 2015a). It means that American railroads are currently in the deploying and implementing process of the PTC systems, such as the Interoperable Electronic Train Management System used by Class I freight railroads and the Advanced Civil Speed Enforcement System (ACSES) used by the National Railroad Passenger Corporation (Amtrak) on the Northeast Corridor. Furthermore, the concept of several terms (e.g. sensor, actuator, disturbance, process input and process output) in the process model are also interpreted through explanatory descriptions with common examples in Table 2.

4.2 Systems-theoretic accident modeling and processes in end-of-track collisions at passenger stations

This section applies the STAMP model to study end-of-track collisions with potential high consequences at passenger stations. Figure 2 shows the general safety control structure of train operations and major safety-related requirements at passenger stations. The general system hazard related to the train operations at the stub-end passenger terminals is the failure of the train to stop at the end of the terminating track and to collide with the bumping post. This hazard should be prevented with system safety constraints, as shown in Figure 2. These general constraints must be enforced by the entire socio-technical control structure at passenger stations to achieve a positive stop before reaching bumping posts. In other words, end-of-track collision at passenger stations results from either lack of or inadequate enforcement of the constraints at a certain hierarchical level. All the hierarchical levels and controllers are interpreted with brief discussions as follows. To clarify, numerous federal agencies and rail industry associations are related to the train operation safety in the USA, while this study only considers some of them that have a close relationship with train operations at passenger stations.

• The US Congress, as the bicameral legislature of the federal government, vests all legislative powers. New laws and changes in existing laws can only be enacted with the consent of the US Congress.

• FRA is an agency in the US Department of Transportation (USDOT) with the mission to facilitate the safe and reliable movement of both passenger and freight in the USA by way of establishment and enactment of safety regulations, promotion of rail infrastructure and services, data-driven analysis and development of emerging technologies and innovative solutions in support of rail safety and operational performance (USDOT, 2017).

• FTA is also an agency within USDOT. It provides financial and technical assistance to public transit, including light rail, subways, buses (FTA, 2018). FTA receives funding authorized by US Congress in transportation legislation, such as the Fixing America’s Surface Transportation Act (Congress of the United States of America, 2015b).

• National Institutes of Health (NIH) is an agency of the US Department of Health and Human Services. NIH publishes and supports foremost medical research studies and some of them could guide the physical examination in railroads. For example, an NIH study of interactions between obesity and obstructive sleep apnea (OSA) (Romero-Corral et al., 2010) found out that a body mass index of more than 35 kg/m² indicates severe obesity and increased risk of OSA.

• NTSB is an independent US government investigative agency that is responsible for transportation accident investigations on aviation, highway, marine, pipeline and railroad modes. Although NTSB has no formal authority to regulate or be directly involved in the operation of transportation, it provides objective viewpoints through conducting independent investigations and making well-considered recommendations to improve transportation safety (NTSB, 2018d).

• Railroad industry associations are the industry groups that represent specific modes of rail transportation. For example, the American Public Transportation Association (APTA) is a nonprofit organization that represents all modes of public transportation (e.g. commuter rail, light rail, subways) in the USA. To achieve safe and economical public transportation services and support the growth of federal investments and resource advocacy, APTA provides manuals for transportation modes, education for the public and training programs for workforce, and lobbies to the US Congress (APTA, 2018). The Association of American Railroads (AAR) primarily represent the seven Class I freight railroads (a group of the largest railroads operating in the USA with each railroad annual operating revenue over US$447.6m in 2016) of North American, Amtrak, some non-Class I, and regional commuter railroads, and rail suppliers (AAR, 2018). Some short line and regional railroads are also represented by the American Short Line and Regional Railroad Association. The American Railway Engineering and Maintenance-of-Way Association is an industry group that develops technical manuals and recommended practices for the railway infrastructure, including the process from design, construction, to maintenance (American Railway Engineering and Maintenance-of-Way Association, 2018).

• Railroads in the USA play a key role in the national economy, with both freight shipment and passenger service. In terms of passenger railroads, Amtrak is the largest intercity passenger railroad that provides national passengers a rail network connecting over 500 destinations in 46 states, as well as three Canadian provinces (Amtrak, 2017). In addition, there is also a list of commuter rails existing in some metropolitan areas, such as Long Island Rail Road (LIRR) and Metro-North Railroad in New York City, NJT in New Jersey, the Massachusetts Bay Transportation Authority in Boston and Metrolink in Southern California. For freight railroads, around 600 freight railroads operating in the USA are privately owned and operated with a nearly 140,000-mile rail network (AAR, 2017). Seven freight railroads (e.g. BNSF, Canadian National, Canadian Pacific, CSX Transportation, Kansas City Southern, Norfolk Southern and Union Pacific) with at least US$447.6m in 2016 revenue are classified as Class I railroads and each operates in a variety of states over thousands of track miles. Based on the latest statistics from AAR (2018), seven Class I railroads contribute to around 69% of freight rail mileage, 90% of employees and 94% of revenue. In addition, hundreds of short line and regional railroads transport the goods across the country in various operation sizes.

• Traincrew members include engineers, conductors or assistant conductors in some cases. FRA (2016a) established minimum requirements for the size of train crew staffs depending on the type of operation and the safety risks. Generally, train engineers and conductors make up the train staff in either freight trains or passenger trains and have the responsibility for safe train operation, as well as providing the operation reports and problem reports to the railroads. To guarantee it, train engineers and conductors are subject to a federally regulated training, qualification, and certification process mandated by 49 Code of Federal Regulations (CFR) Part 240 and Part 242, respectively.

Furthermore, effective communication channels between the hierarchical levels are essential (Figure 2). For example, in the communication channels between US Congress and FRA, Congress establishes and enacts legislation as well as grants budgets to FRA. In return, the FRA needs to submit government reports so that Congress can attain information on proposed legislation, oversee the activities of the government agency and evaluate the implementation of federal laws (GPO, 2018). In terms of the connections between FRA and railroads, the FRA has the responsibility for making regulations and certifications for the railroad industry, as well as the supervision of railroads’ execution, in the USA. The rules and regulations are published in the form of Federal Register and the CFR. Some safety recommendations and standards are also published by FRA, such as a safety advisory to remind railroads of the significance of compliance with restricted speed operating rules (FRA, 2012), an updated passenger equipment safety standard for high-speed trains that can travel up to 220 miles per hour (FRA, 2016b). Conversely, railroads must work out necessary accident/incident reports, implementation plans and operations reports. Moreover, the PTC system in the operating process (Figure 1) is excluded in the control structure at passenger stations (Figure 2) because current regulations (FRA, 2011) designate train operations at passenger stations as a regulatory exemption from the PTC requirement, which would be further discussed in following sections.

5.1 Accident narratives

Most accident information and probable causes mentioned in this paper refer to NTSB accident investigation reports (NTSB, 2018a, 2018b, 2018c) and the FRA database (FRA, 2018). More accident details and investigation results are also available in these references. This section only briefly summarizes crucial accident information to support the analysis of end-of-track collisions at passenger stations using STAMP model.

An NJT collision accident at Hoboken Terminal occurred on September 29, 2016, at about 8:38 a.m. (Eastern Standard Time). An NJT train failed to stop short of the stub end of track 5 and overrode a bumping post, which is a rigid structure that is level with the train’s coupler at the end of the track, then the train struck a wall of the Hoboken Terminal in New Jersey, USA (Figure 3). NJT is a state-owned public transportation system that has served the state of New Jersey since 1979. It connects the major commercial center and employment hubs within New Jersey, as well as some neighboring major cities of New York and Philadelphia. NJT is the nation’s largest statewide public transportation system that provides around 270 million passenger trips totally in the fiscal year 2017 (NJ Transit, 2018).

According to the locomotive event recorder data released by NTSB (2018b), the train was traveling about 8 mph at about 38 s before the collision and the throttle position went from idle to the number 4. As a result, the train speed started to increase and reached about 21 mph. Just less than 1 s before the collision occurred, emergency braking was applied by the engineer and train speed at the time of the collision was still documented as 21 mph in the locomotive event recorder. The accident train includes one cab car, three passenger cars and one locomotive at the rear with about 250 passengers and three crewmembers (engineer, conductor and assistant conductor). A total of 110 people got injured and one person on the passenger platform was killed by the falling debris (NTSB, 2018b). The total damage to the equipment, track, signal and structural damage was over US$6m (FRA, 2018).

5.2 Stamp-based analysis in New Jersey Transit accident at Hoboken Terminal

As an end-of-track collision at terminal, the Hoboken accident roughly has the identical operation safety control structure as developed in Figure 2. The general system hazard related to NJT accident is identified as a failure to stop at the end of the terminating track where it struck the bumping post. This hazard is restrained through the constraints that are applied by the entire socio-technical control structure to enforce safe train operations at passenger stations. Instead of distributing blame or responsibility to any controller, following further discussions aim to understand the occurrence of the NJT accident and to analyze its inadequate control actions in this complex train operation system at the passenger station. Detailed analysis of inadequate enforcement is extended with selected system components’ safety constraints, failures or inadequate control actions and supportive backgrounds, as shown in Figure 4.

6.1 Obstructive sleep apnea

OSA is one major contributing factor to fragmented sleep and subsequent daytime fatigue sleepiness, which could be a crucial increasing risk for train crewmembers. In a study of train engineers in Greece, Nena et al. (2008) concluded that OSA was common among Greek railway drivers and 62% of train engineers encountered this sleep-disorder issue, while the percentage of adults having OSA in the general population from Western countries was only around 5% (Young et al., 2002). Similarly, Koyama et al. (2012) studied the prevalence of OSA among Brazilian railroad workers. Based on an evaluation of a survey from 745 railroad workers, the prevalence of OSA was approximately 35%, which is higher than that in the general population too. Without OSA screening and diagnosis programs required by federal agencies or railroads, a relatively high prevalence in the train engineers of OSA would possibly increase the risk of end-of-track collisions at passenger stations. According to an NTSB report (NTSB, 2018a), the engineer in the NJT accident underwent a post-accident study and was diagnosed with severe OSA, which was a probable cause of this accident. Nevertheless, at the time of the collision, there were no regulatory guidelines or recommendations referring to effective diagnosis and follow-up medical treatment in respect to OSA. This STAMP-based accident analysis demonstrates the necessity for government agencies, railroad associations and railroad companies to work closely to promote the development and enforcement of a complete, effective program involving OSA screening and follow-up medical treatment. To achieve this, extensive research studies could contribute to the development of an effective OSA program. Romero-Corral et al. (2010) disclosed the interactions between body weight (measured by BMI) and OSA, which were also used in the investigation of NJT train engineer after accidents by NTSB (2018b, 2018c). Epstein et al. (2009) provided a comprehensive clinical guideline for the evaluation and treatment of OSA. The diagnostic of OSA was suggested to involve a sleep-oriented history, physical examination and objective testing. Once the diagnosis is set up, the patient should consider an appropriate treatment strategy that covers positive airway pressure devices, oral appliances, behavioral treatments, surgery and/or adjunctive treatments (Epstein et al., 2009). With the support from existing but limited OSA screening practices and literature, a comprehensive, valid OSA program can be developed to mitigate the risk from OSA posing to intercity passenger trains and commuter trains. An intervention policy with regulatory guidelines and recommendations referring to diagnosis and follow-up medical treatment are paramount to detect OSA and other sleep disorders among train crewmembers. In this case, the railroad employees in safety-sensitive positions should meet medical standards to be fit for duty, which is able to reduce such human-factor-related train accidents.

Figure 5 provides a visual interpretation of the proposed recommendation in the STAMP model. More specifically, a practical OSA program involving both screening and treatment can be developed based on the guidance from NIH and would be valid for train crew members who should be fit for duty under the OSA program to release more positive commands in the train operations at passenger stations.

6.2 System safety program plans

As mentioned in Section 5, NJT had SSPP with rich hazard management to monitor train operations and collect considerable data to identify emerging safety issues. Although six collisions have also occurred between NJT trains and bumping posts between 2007 and 2016 (two of them at Hoboken Terminal), NTSB (2018a) pointed out that NJT did not recognize the risk of an end-of-track collision at passenger stations as a key risk factor in SSPP. Similarly, the SSPP overlooked the need for OSA screening and treatment to prevent potential hazards and did not account for undiagnosed or untreated OSA. Therefore, SSPP should be promoted and updated with the account for the increased risk of OSA and operational hazards associated with end-of-track collisions. Eventually, the robust SSPP documenting comprehensive hazards can contribute to the mitigation of emerging, critical risk elements through an effective management system.

In Figure 5, the proposed robust SSPP is interpreted visually using simplified STAMP. In addition to adding end-of-track collisions and OSA into the SSPP, federal agencies (e.g. FRA or FTA), industry associations (e.g. APTA) and railroads can construct a reliable SSPP with comprehensive hazards documented. This action would promote the level of safe train operations (commands in Figure 5) by train crewmembers. Moreover, the reports and feedbacks from the train operation process can also advance an exhaustive, continuous safety management system and eventually mitigate the risk at passenger stations before the accident occurred.

6.3 Collision avoidance and mitigation techniques

6.4 Bumping post with more impact tolerance

Bumping post, also known as bumper block, buffer stop, is an attenuating safety device placed at the end of terminating track to stop unauthorized movement. In the NJT accident at Hoboken Terminal, the bumping post (an exemplar shown in Figure 8(a)) located at the end of the tracks was overrode and destroyed by the accident trains. NTSB (2018a) concluded that the bumping post at the accident location did not by itself provide protection at passenger stations adequately. The fixed bumping posts, of the type employed at Hoboken Terminal can only offer tolerance and protection for low-speed impact. In theory, a train transfers enormous kinetic energy to the bumping post in an impact (e.g. end-of-track collision) and can easily exceed the bumper’s tolerance. After hitting the bumping post, the accident train stuck a wall of the terminal and also led to one person on the passenger platform died due to the falling debris from the Hoboken Terminal.

In addition to the fixed bumping post that was implemented in the NJT accident, energy absorbing bumping posts (Figure 8(b)) are dynamic barriers that utilize friction mechanisms and hydraulic systems and can absorb relatively higher-speed impact. However, NTSB (2018a) pointed out that most terminals do not have the physical space for this type of bumping post, in particular for the friction mechanisms with extensive distance demand. Moreover, Moturu and Utterback (2018) identified that energy absorbing bumping posts are still limited in the amount of kinetic energy that they can tolerate and would have a large likelihood to fail at speeds over 10 mph. It means even if this type of bumping post was equipped, it still cannot bear the impact of the NJT train at Hoboken Terminal, which was traveling around 21 mph at the time of the accident. Therefore, it is essential to design and implement bumping posts with both higher impact tolerance and more practical function in the complex station areas. Figure 8 visually indicates how advanced bumping posts increase the level of safe train operations at passenger stations. Advanced bumping posts located at the end of the terminating track can strengthen the impact tolerance to the uncompliant train movements. As a result, the potential collision consequence (process output in Figure 8) under reinforcing collision protection device would be reduced.

It is acknowledged that there is always an upper limit of allowed impact speed for this impact absorbing device. In practice, bumping post should be coupled with the aforementioned end-of-track collision risk mitigation strategies (e.g. OSA screening program, train protection systems, comprehensive SSPP) to effectively prevent end-of-track collisions in the nationwide rail system.