The ability effectively to enforce basic traffic rules against offending drivers is a key tool in increasing road safety, as is the awareness among the motoring public that enforcement is in operation (See Policing and Enforcement).

Enforcement – Red Light

Red-light running is a major traffic safety issue. In the USA, it is accounts for some 800 deaths and an estimated 165,000 injuries a year. Automated camera enforcement provides the evidence necessary for prosecution.

Enforcement - Speed

Speed enforcement is becoming more sophisticated and driver-friendly. Conventionally the main technique has been the use of single-point “spot” speed cameras, which record the driver exceeding the limit as they pass by. In the UK, speed cameras of this kind have often drawn hostility from motorists who perceive it as an unfair means of raising money from enforcement fines.

Speed over distance (SOD) or average speed enforcement (ASE) are seen as fairer methods.

Average speed enforcement is demonstrating higher levels of compliance than spot-speed in a number of European countries where it has been deployed.

“Soft” speed enforcement aims to influence driver behaviour – it does not impose legal or financial penalties. A European example involves detecting a vehicle as it approaches from a measured point ahead, which allows the time needed to cover the distance to be calculated to determine whether the vehicle is speeding. This can trigger a dynamic message sign to display a warning message. (See Vulnerable Road Users)

Beneficial ITS vehicle technologies include:

• anti-lock braking
• electronic stability control
• collision warning
• adaptive cruise control
• parking management
• driver drowsiness detection

The basis of all these systems, and the safety benefits that they bring, is the development of on-board sensors linked to the vehicle’s engine management and braking systems. (See Driver Support)

Anti-lock braking systems (ABS) intervene to help stop loss of vehicle traction (skidding – for example, in icy weather or wet conditions). ABS works closely with electronic stability control (ESC), which detects the loss of steering control and applies the brakes individually to the wheels to correct the steering. The US Insurance Institute for Highway Safety and the US National Highway Traffic Safety Administration estimate that comprehensive use of the technology could avoid one-third of fatal road traffic accidents.

Crash avoidance systems use autonomous braking, which comes into effect if a driver fails to brake in time. The technology is an advance on the (widely-used) autonomous cruise control, which automatically adjusts a vehicle’s speed to keep it a safe distance behind traffic ahead. Both the US and the EU are moving towards making mandatory, the fitting of frontal collision warning systems. Automotive manufacturers have started to include these systems into their production lines. The EU estimates that these will save 5,000 deaths and 50,000 serious injuries a year.

Automatic parking uses sensors to detect the presence of objects around a vehicle to guide the vehicle safely into a clear space.

Driver drowsiness detection is a response to studies that suggest that up to 20% of road traffic accidents are due to fatigue. It works by monitoring a vehicle’s movements and assessing the likelihood of these being controlled or uncontrolled.

ISA systems are based on satellite navigation equipment that will determine a vehicle’s position. The digital map used for navigation can be expanded to include precise details of the start and end locations for speed limits as well as other information – such as road geometry and route numbers and place names. The vehicle speed is automatically adjusted to take account of the speed limit (See Intelligent Speed Adaptation).

The main ISA options are:

• advisory: to provide the speed limit and warn the driver when this is exceeded
• mandatory: when the speed limit is set and the system makes it difficult or impossible to exceed – some systems allow the driver to accelerate out of an emergency situation by overriding the system.

Trials indicate the potential for safety, efficiency and improvements – including 42% reductions in fatal crashes, fuel efficiency gains of 5%, and smoother traffic flows resulting in less congestion (See: http://www-nrd.nhtsa.dot.gov/pdf/esv/esv20/07-0247-W.pdf).

Widespread adoption of ISA could bring the additional benefit of reduced insurance costs. In Europe, ISA systems that meet European New Car Assessment Programme (Euro NCAP) requirements gain an advantage in relation to the car’s overall ‘Safety Assist’ rating.

Fast detection of a traffic accident – particularly in a tunnel or on a bridge where there are physical and geographical restrictions – is essential to trigger a rapid response. Resources need to be deployed to deal with casualties, remove obstructions, provide driver alerts and – if necessary – divert oncoming traffic, and restore normal running conditions as soon as possible (See Traffic Incidents).

Automatic Incident Detection (AID) systems use cameras and traffic monitoring technology to record and analyse traffic data and quickly detect incidents using motorway incident detection systems. A sudden build-up of congestion, for example, can indicate that there is an incident ahead.

Response times to road traffic accidents and medical emergencies are critical, with the ‘golden 15 minutes’ typically cited as the optimum window for early and effective treatment. The key needs are fast response and accurate direction to accident scenes. Automatic traffic signal priority for emergency vehicles is increasingly common.

ITS technologies introduced to speed up the process include automatic crash notification systems, which many automotive manufacturers are building into their vehicles. These work by sensing an impact and sending out an automatic alert via mobile phone networks to a call centre. In Europe, the EU’s eCall (emergency Call) initiative aims to mandate, from 2018, European automotive manufactures to install these systems.

Emergency service providers can make use of real-time dynamic route guidance systems to dispatch and route vehicles around known congestion and roadworks to minimise response and return times. Speeding ambulances, themselves, risk causing, or being involved in, road traffic accidents. The US General Services Administration records over 6,000 ambulance crashes a year. In-vehicle ‘black boxes’ can monitor and record driver behaviour and highlight training needs.

Road construction workzones are vulnerable locations for road users and site workers – especially at night when it is less disturbing to traffic than in the daytime. It is important for traffic to be managed through the work zone at safe speeds. Construction workers are close to moving traffic and need to be protected – as many vehicles exceed recommended speeds (See Work Zones).

Workzone traffic management schemes can draw on ITS technologies such as Bluetooth detection, which anonymously registers the passing of vehicles carrying Bluetooth devices (See Wireless Telecommunications). This provided the US state of Texas with a cost-effective alternative for monitoring the speed of vehicles over a lengthy section of road reconstruction on the I-35 highway.

There are examples of basic roadworks equipment being equipped with ITS features to provide a safety role. For example:

• detection sensors fitted in the flashing lanterns installed on US traffic barriers will collect real-time speeds from passing vehicles for processing to set speed warning signs – benefits in terms of accident rate reductions are estimated variously between 15% – 66%
• traffic cones can be upgraded and converted into wireless sensor perimeters to detect and report an impact at any point around a workzone for fast detection to initiate rapid response.

In rural areas, intersection crashes typically occur less often than in urban ones. They are often more severe because of the higher vehicle speeds and the consequences can be more serious because of longer emergency response times. New intersection decision support systems use traffic sensors and advanced computing to monitor vehicles moving along rural divided highways (dual carriageways). They process the data generated to alert drivers waiting to merge with, or cross, the traffic – when the gaps are too short for them to be able to do so safely.

Wild Animals

Collisions with wild animals on rural roads are increasing wherever human development spreads. This is an issue of growing relevance to developing and emerging economies. A crash involving a large animal can cause death, serious injury, severe vehicle damage and disruption to other road users. Physical defences such as fencing and over/underpasses are not always possible or cost-effective, given access and maintenance issues. In-vehicle and roadside systems are being developed to detect large animals. The sensors can distinguish between moving vehicles (with warm engines) and animals, alerting drivers to their presence (See Information and Warning).

People want healthy, attractive and comfortable living environments. Tough air quality standards are being imposed in many countries. One way of enforcing these standards is by creating low emissions zones (LEZs) – such as those introduced in Sweden in 1996. Vehicles which do not comply with the emission standards are required to pay a penalty charge. Automated enforcement is typically by camera supported by ITS-enabled back-office enforcement operations.

The enforcement of vehicle emissions legislation – such as the Euro standards introduced in Europe in 1993 and subsequently adopted in other parts of the world – encourages the use of cleaner road vehicles. It does so by putting pressure on operators to accelerate vehicle replacement or to fit their existing vehicles with pollution reducing equipment. In Berlin, the share of compliant diesel-engine vehicles rose by 38% between 2006 and 2011 – largely because fleet operators installed diesel particle filters.

The cost of setting up the London (UK) LEZ was comparatively low because it made large-scale use of the city’s existing congestion charging infrastructure. Creating an LEZ using existing enforcement infrastructure – as in the London case – makes economic sense.

Noise pollution tends to attract less public concern than air pollution but it is a growing nuisance and poses a health hazard to people living on or near sites experiencing high levels of traffic noise. Traffic models for forecasting traffic noise impacts are emerging which take advantage of readily-available data on road geometry and the built environment.

CO2 and noise emissions often respond to similar solutions:

• promoting the use of electric/hybrid rather than petrol or diesel engine vehicles
• Low Emission Zones (LEZ) can contribute to reducing noise pollution – since vehicles complying with higher emissions standards are generally quieter than older ones
• encouraging modal shift from road vehicles to public transport
• enforcing existing speed limits and introducing lower limits in specific situations –for example, 32km/h zones in residential areas

Cities can become cluttered with street furniture installed for traffic management and the safety of road users and pedestrians. The additional infrastructure (gantries, roadside cabinets and mounting posts) for ITS deployments – such as cameras for congestion charging enforcement, and on-street sensors for air quality monitoring – add to the clutter. This can be a serious issue in unspoilt rural areas and historic town centres – where tourism brings economic benefits.

There are ways to mitigate the visual impact of ITS equipment. For example:

• a reduction in the number and size of gantries for tolling equipment is possible by rationalising the equipment required
• satellite-based charging systems are now proven technology and will reduce the scale of physical tolling infrastructure
• air quality information – needed for traffic management that can reduce pollution levels – is possible to collect using very small sensors or ‘motes’ that can be attached unobtrusively to buildings, existing street furniture, vehicles – and even on people

In time, it is possible (with good design and appropriate technology) that cooperative vehicle systems may reduce the need for invasive ITS installations on roads – since they will automatically collect, process and transfer data and traffic information between vehicles, the roadside and drivers.

Transport links, the availability and quality of public transport, journey times and reliability are important factors for local communities and in deciding where to locate businesses.

When people and businesses relocate the more well-informed they are about transport options, the more likely they are to opt for well-connected locations. In North America, Australia and New Zealand, neighbourhood rating systems and journey planning which makes use of data from public transport operators, cyclists and pedestrians to highlight areas with good facilities.

ITS can also be used to manage and monitor environmental zones. For example, DMS and VMS can be used for signing the zone, especially if different access regimes apply to drivers at different times. ITS can also be used in air quality monitoring and in communicating the results to stakeholders. Example of these are:

• Queensland, Australia – where the South East Queensland Air Quality model uses GIS to map current air quality and for forecasting in connection with land use and transport planning decisions. The GIS maps are also used as a communications tool, to inform about air quality and promote the need to improve it
• Turin, Italy – where ITS is deployed for traffic management and public transport operations in response to pollution forecasts to reduce the severity of poor air quality.

ITS has been used as part of a coordinated approach to promote travel choices that will help reduce congestion and pollution in cities. It provides:

• the tools to implement road pricing and congestion charging, in order to discourage or modify traffic demands
• facilities to improve the attractiveness of alternatives such as public transport, car-sharing, carpooling, and cycling

Car pooling 

Car pooling (also known as ride-sharing) and car clubs are enjoying a boom, thanks to ITS technologies. ITS applications such as a car pool database (of drivers offering spare seats and potential passengers looking for a ride) – together with a user forum – can enable planned sharing of car journeys. Car pooling reduces individuals’ fuel, parking and toll costs – and in the USA, allows them use of dedicated high-occupancy vehicle (HOV) lanes. It helps to reduce traffic demand, cut emissions and relieve the pressure on parking. Employers can offer and promote schemes as an incentive to their workforces.

Car clubs provide members with the use of a car on an as-needed basis for specific journeys – delivering them savings on insurance, depreciation and road taxes. Local governments around the world are promoting schemes on their travel websites as making useful contributions to modal shift. Booking is by phone or internet. For some schemes, a member’s smartcard opens the vehicle and is used to process payment for use and fuel from the member’s account. Transport for London calculates that those driving fewer than 9,600km a year can save up to £3,500 as compared with owning a car.

Cycling

Cycling is gaining popularity worldwide as an alternative travel mode, one that is attractive on personal and public health grounds. On busy urban roads, cyclists are vulnerable – particularly prone to collisions with heavy goods vehicles (HGVs) overtaking or making turning movements at road junctions. ITS-enabled protective systems being investigated include:

• controlling access by HGVs in city centres – with electronic charging or access control and automated enforcement
• fitting HGVs with video cameras that pick up images of cyclists at risk in the danger zone around the vehicles – and flash an audible or visual alert to their drivers
• an identification system, with cyclists wearing a transponder (similar to an in-vehicle toll tag) that is read by an HGV’s on-board unit and again warns the driver

Town and city authorities want road networks that run smoothly and efficiently, for the benefit of residents, businesses and visitors. The quality of transport in a city is a central factor for business investment and location decisions, maintaining and increasing income from tourism, and building electoral support for local politicians. ITS systems such as urban traffic control (UTC) are valuable tools for those responsible for management of the infrastructure (See Urban Operations).

Urban Traffic Control

Urban traffic Control (UTS – also known as Area Traffic Control) is one of the world’s longest-established ITS applications, with its origins in the 1970s in response to growing car ownership that led to congestion on city streets. UTC provides the means to monitor road traffic flows in built-up areas, and modify these in response to congestion and other conflicts (for example, the balance between public transport and private cars). One way is by automatically adjusting traffic signal phases at intersections in response to flows and the needs of public transport vehicles (See Urban Traffic Control).

Widely used UTC systems around the world include:

• SCOOT, developed in the UK and increasingly being taken up in other countries across the world
• SCATS, developed in Australia and now in use in much of Asia
• the Open Traffic Systems (OTS)/Open Communication Interface for Road Traffic Control Systems (OCIT) specifications used in German-speaking areas of Europe
• comtrol systems based on standards contained within the US National Transportation Communications for ITS Protocol (NTCIP)

Integrated Systems

UTC installations form the core of more developed and sophisticated arrays of urban ITS applications that expand their functions by linking in additional capabilities. They do this by introducing common databases and data dictionary, allowing the mechanisms (such as cameras and sensors) used for traffic management, parking management, traffic signal control for priority for buses, air quality management in response to pollution, and weather monitoring to communicate and share information with each other via a single, integrated control centre (See Urban Networks).

Major benefits include:

• improved journey times
• improved air quality from reducing air pollution generated by slow-moving traffic
• reduced delays to public transport
• traffic speed control
• protection of historic and environmentally-sensitive areas

Central to integrated operations is the adoption of agreed open standards and specifications for products across the ITS industry, to ensure their interoperability. Open specifications make it possible easily to add fresh functions when needed, and free local governments from dependence on individual suppliers when it comes to needing replacement parts or system upgrades. Agencies can then shop around for the most competitive prices and service offers, which in turn stimulates innovative commercial development (See ITS Standards).

Drivers searching for parking space can add significantly to urban congestion. Parking guidance systems monitor space availability on-street or in car parks via in-bay sensors that detect vehicle presence and give drivers the resulting information through VMS or via smartphone apps. When a car overstays its paid-for time, the system can alert enforcement officials, who then need to spend less time patrolling and can be deployed more efficiently.

Smart parking deployments give car park operators and city governments useful data on levels of demand. They can use this information to adjust charges, levying higher rates to increase turnover on their busiest sites, and lower ones to attract drivers to underused spaces.

Interurban highways need to run smoothly and efficiently, avoiding congestion and delays. These can also impact on connecting local roads and spread disruption further. The operator need to ensure they are making the best possible use of their existing road assets, to avoid or delay the cost and environmental disruption of adding new lanes – for which ramp metering and monitoring of usage at different points of the network is helpful (See Highway Operations).

Highway management systems

Highway management systems include automatic incident detection, CCTV for the benefit of control centre operators, automation of traffic flow monitoring and software to control speed limits before queues occur. Case studies have shown the delay-savings benefits achievable from the strategic use of variable message signs (VMS) give a positive cost-benefit which justifies the initial capital investment. For example, queue protection systems deliver significant socio-economic benefits from reducing numbers of killed and seriously injured road-users. They also produced significant secondary benefits through incident-delay savings (See Highway Traffic).

Savings from cost reductions in journey times are important to all road users, but the benefits are most relevant to the operators of vehicle fleets and highway infrastructures. The quantifiable benefits come in one of two ways:

• delay-savings through diverting traffic away from the incident along a less congested route since, while the journey time may be greater, delays on the approaches to an incident and lengthy carriageway closures can be considerably greater and extend the journey time even more
• less congestion on the approach to the incident, aiding a quicker recovery of normal traffic flows once the incident is cleared.

HOV and HOT

In the USA highway management techniques commonly include high occupancy vehicle (HOV) and high occupancy toll (HOT) lanes on motorways and expressways.

HOV lanes, introduced in the US in the 1970s and later adopted in Australia and New Zealand – though rare in Europe - are open to cars carrying at least two passengers (for example, in car sharing schemes), and buses and, sometimes, green (low emission) vehicles. The aim is to increase higher average vehicle occupancy and person throughput with the goal of reducing traffic congestion and air pollution. Some HOV lanes are reversible, to accommodate differing peak flows.

HOT lanes give drivers of single-occupancy vehicles access to HOV lanes on payment of a charge levied by, for example, by automatic number plate recognition, or electronic fee collection (EFC). Tolls can increase in line with traffic density as this increases within the lanes, to reduce the risk of their becoming congested.

In the Los Angeles HOT system, drivers use specially-developed "switchable" transponders to indicate the number of occupants. The EFC reader that picks up the setting uses it to decide automatically on chargeability. For enforcement, a beacon near the EFC reader lights up in response to the scanning and alerts highway patrol officers to check the stated occupancy setting.

Managed Motorways

So-called “Smart” or managed motorway sections use ITS technologies for active traffic management to control flow and speeds and give users relevant information on overhead variable message signs (VMS), to help them make the best use of heavily congested segments. They can impose variable speed limits (VSLs) where the speed limit is altered to reflect current traffic conditions.

Traffic sensors detect slow-moving and stationary traffic and alert HA regional control centres to the changing conditions. These set relevant VMS messages and variable speed limit signs (VSL) to correspond with traffic movements. The “Dynamic Roadspace Utilization Manager (DRUM) is another good example of ITS software application that has been applied to great advantage during contruction works on an active motorway. The principle is based on first cone-on and last cone-off approach to road work closures.

See: http://trl.co.uk/software/software_products/drum.htm

Freight movements have an essential part to play in the local economy, but delivery vans, articulated trucks and other heavy vehicles can also be a source of nuisance – because of increased accidents, congestion, noise nuisance and environmental pollution. Many city streets are not suitable for large vehicles; moreover loading and unloading activities can be a major source of obstruction to moving traffic. Some cities impose restrictions at different times of day (night-time lorry bans in residential areas, daytime restrictions on deliveries in shopping streets and touristic localities). ITS technologies are useful in these circumstance as a means for vehicle identification and controlling access (See Operations & Fleet Management).

Freight consolidation centres (FCCs), located at points close to town centres or shopping malls and major road junctions, help to avoid or reduce the impact of Heavy Goods Vehicles (HGVs) on urban roads. They can help mitigate traffic congestion and may have a positive impact on local air pollution. Using logistics tracking and tracing systems, they take in large incoming consignments destined for numbers of in-town retailers, for breaking up into individual loads. These then travel on by smaller and less polluting vehicles at convenient times over the final leg. There are currently over 114 FCCs worldwide, mostly in the EU – specifically France, Germany, Italy, the Netherlands and the UK.

A system deployed in the Netherlands and elsewhere in Europe rewards truck drivers whose driving is environmentally-friendly with green lights at intersections. It interfaces with the city’s signal control network and incorporates data on cities’ speed limits, encouraging compliance with these by integrating with trucks’ own engine management system for speed limiting and acceleration monitoring. A dashboard display keeps drivers informed on their performance and fuel consumption and driving performance, with low scores generating warnings.

Commercial drivers and their vehicles can be a reliable source of information on current traffic conditions the network. Increasing use of just-in-time deliveries means that vehicle fleet operations managers and drivers are increasingly interested in the real-time status of urban road networks.

Overweight and over-height vehicles pose real threats to road safety and transport infrastructure. Systematic enforcement against overloading of trucks is a cost-effective way of reducing damage to the road pavement. Weigh-in-motion systems save trucks time by checking their safety status as they drive over measurement plates at highway speeds. In the US, a developed version also checks trucking company and driver credentials by automatically accessing electronic data banks, enabling officials to focus on trucks that are likely to be suspect and achieve higher success rates. The US DOT estimates that manual checks can save around 0.7% of road traffic accidents involving trucks (approximately 440,000 each year). Automated screening can improve this to above 3.5% (See Weight Screening).

Major events place abnormal pressures on road and public transport networks because people come in large numbers. In addition, travel demand is often concentrated into comparatively short periods of time as people arrive and leave the event. The events can be regular or exceptional – and last for a day (as with sports fixtures), weeks (Olympics/Paralympics) or may continue for months (festivals).

Successful management of a major event requires close coordination between all parties: the event promoters, the authorities for roads and highways that are affected, the police, emergency services and transport operators. There may be heavy reliance on ITS – for example VMS to keep travellers informed about current options and CCTV to assist the network controllers in their tasks. At the same time, costs of additional equipment that may be needed for only a short period for non-recurrent events demand careful scrutiny (See Planned Events).

The connected vehicle concept is the subject of major ITS research programmes in a number countries including Europe, the USA and Australia. Techniques for two-way wireless communication of data, vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I), are being developed to increase road safety and mobility. Related telematics services such as Automatic Crash Notification and breakdown call button are direct results of the connected vehicles concept. (See The Connected Vehicle - PIARC Report)

Over and above its main aim of safety, V2I can help to reduce the delays and congestion resulting from road traffic accidents. V2I keeps vehicles in electronic contact with the roadside infrastructure, not only to help avoid crashes but also decrease the environmental impacts of traffic by smoothing traffic flow and minimising rapid accelerations and decelerations. One specific benefit being piloted is the ability to transmit traffic signal phase and timing information directly into the vehicle at upcoming intersections.

With V2V, vehicles ‘sense’ potential dangers by means of detectors that determine the presence of other vehicles, their positions and speeds. The on-board systems will then warn drivers and/or intervene automatically in engine management or braking systems, to avoid an accident.

Eventually, the hope is that V2V and V2I will reduce both the quantity and size of roadside infrastructure, by sending important safety- and mobility-related information directly into vehicles (See Warning & Control System).

A European project is working on methods of mining the data gathered by ITS installations to measure levels of road usage and so be able to predict more accurately when maintenance is likely to be needed. The approach could also allow consideration of more environmentally-friendly options in road maintenance programmes, for example to give priority to noise reduction.

For monitoring individual ITS installations in operation, the concept of an ‘online filing cabinet’ for storing information can help road maintenance engineers progressively improve overall performance rather than simply reacting to faults being notified. There is even the prospect of locating wireless sensors into road surfaces, to gather and relay information on condition and maintenance needs.

In the event of an incident or spill of hazardous materials (HazMat) the emergency services personnel need timely and accurate information about the vehicle location and nature and contents of consignments, so they can respond appropriately and maintain safety for the public and other road users (See Safety Information Exchange).

In the USA freight carriers move an estimated 700,000 shipments of hazardous materials every day. Electronic access to carriers’ databases for early identification of the vehicle and cargo enables responders to:

• save community resources by reducing routine HazMat team response times, unnecessary evacuations, and unjustified highway closures
• minimise resources expended in typically assuming a worst-case scenario and committing unnecessary levels of equipment and personnel
• minimise environmental and public health impacts by restricting the quantity of hazardous material that escapes, reducing the area affected and the extent of clean-up needed, and initiating mitigation measures more quickly

Natural disasters play havoc with the transportation infrastructure which is, at the same time, vital to keep operating as well as possible as a means of rescue and evacuation and bringing in supplies and equipment (See Emergency Response).

In humanitarian relief supply chains, ITS plays a key role in the last 1km-2km delivery from a local distribution centre (LDC) to affected populations. Computerised management of available vehicles and planning of delivery schedules can optimise resource allocation and routing decisions with the aim of minimising transportation costs and maximising benefits for those in need. This can be particularly important for disasters in developing countries with inadequate road networks.

Existing traffic management systems can play vital supporting roles. Bluetooth-based traffic monitoring proved effective when a factory in Texas caught fire and later exploded. Residents needed immediate evacuation, with school buses and ambulances coming in to rescue them and needing priority access.

Terrorist attacks – and the threat of them – are now facts of life in many parts of the world. Transport infrastructure is a natural target because of the large numbers of potential victims and the effects of the resulting disruption on much larger numbers of people and on regional and local economies.

Particularly vulnerable are large numbers of passengers moving through confined spaces, for example, transport termini and interchanges – and metro stations. Passenger evacuation systems depend for their effectiveness on the amount and quality of information made available. Simulations can model individual passenger movements to provide for the needs of the elderly and disabled, and integrate planned lifts and escalators for the capacity calculations needed to estimate realistic evacuation times.

Prevention of terrorist acts can be strengthened by systems for the early detection of would-be perpetrators. Analysis of CCTV footage of rail and bus stations can detect people making unusual movements.