1 Introduction

New technologies in communication and robotics have had a substantial influence on our daily lifestyle of which transportation is no exception. These technologies have given rise to the prospect of autonomous vehicle (AV) technology which aims to reduce crashes, energy consumption, pollution, and congestion while at the same time increasing transport accessibility. Although the idea of driverless vehicles has been around for decades, the exorbitant costs have hindered large-scale production [1]. Nevertheless, there has been an acceleration in the research and development efforts in the last decade to bring the idea of the AV to fruition. For example, the advent of the Google car brought AVs to the spotlight [2, 3]. Moreover, the automotive industry spends around €77 billion worldwide on R&D in order to nurture innovation and to stay competitive [4, 5].

The rapid development of communication technology and the need to cater to the aging population in developed countries has potentially made AVs a necessity and a vital business paradigm [6]. In light of looming new ideas and technologies such as social networks, smart phones, and AVs, some scholars have emphatically warned that the landscape of transportation is rapidly changing [79]. An example is Uber which is sweeping cities to the extent that taxi companies are struggling to retain business and to remain competitive. Manyika et al. [10] includes vehicle automation on the list of the top ten disruptive technologies of the future.

As a result of fierce competition among car manufacturers, the year 2020 has been slated as a horizon year to offer commercial AVs to the general market [1, 11]. Figure 1 provides an overview of the competition between the giant car makers [12]. Perhaps, the middle of the current century will be the maturity years of the AV market. Based on the deployment and adoption of previous smart vehicle technologies (like automatic transmission and hybrid-electric drive) [13], the forecast is that AVs are expected to constitute around 50 % of vehicle sales, 30 % of vehicles, and 40 % of all vehicle travel by 2040. Therefore, it is incredibly important to be prepared for such eventualities and to understand the challenges that lie ahead while embracing and welcoming the ensuing opportunities.

Fig. 1
figure 1

Expected specification of autonomous vehicles by the year 2020 (courtesy [12])

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The AV is associated with a variety of positive societal impacts such as a safer transport system, a lower cost of transport as well as enabling a modicum of mobility to the non-ambulatory and disabled as well as to those in lower income households. It is estimated that the direct societal value that will be created will be between 0.2 and 1.9 trillion dollars annually by 2025 [10]. Such positive impacts are the driving forces behind the emergence of AV technology, making it a viable, economic model in the near future and beyond.

Some believe that AVs must be viewed through a wide-angled lens, as a multidisciplinary technology. Maddox et al. [14] depicted the AV in a figure with two additional components to ensure a successful working AV paradigm: “Connected” and “Big Data.” Accordingly, the terms “Connected” or “Connected Vehicle” refer to the technologies that ensure communication between all contributing agents or stakeholders including pedestrians, authorities and vehicles, as well as infrastructure.Footnote 1 Figure 2 depicts a conceptual representation of a connected system. The connected component will require a massive amount of data from a variety of sources. As a result, “Big Data” is a term used to highlight the importance of handling such an unprecedented amount of information for which special provisions including software and hardware will be required.

Fig. 2
figure 2

A representation of connected vehicles and infrastructure (courtesy of [16])

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Each of these components is or has been the subject of extensive research in various fields. As such, AV technology could be considered at the crossroads of many disciplines such as transportation science, electrical engineering, information technology, software and hardware engineering, law, ethics, and philosophy. In this article, we look at the AV from a transportation point of view. We aim to shed light on the overarching implications of the AV for scholars, policy makers, planners, and practitioners involved in the transportation sectorFootnote 2.

In particular, we elaborate on features directly pertaining to transport planning such as safety, fuel consumption, road pricing and parking requirements, land use, and demand forecasting. We also touch on other related issues such as cybersecurity, law/regulation, as well as ethical concerns.

The aim is to highlight the opportunities and the challenges that may arise from the introduction and application of AVs. First we shall consider AV within the context of existing transportation systems and society at large, as well as define some related terminologies. We will then endeavor to show the impact of AVs for the short- and long-term future based on previous studies. In order to do this, we have reviewed over 118 references related to AV technology which have been published mainly in the past 5 years so as to provide a comprehensive and updated narrative.

Interestingly, the existing literature does not discuss the methods by which AVs find and determine their routes in the road networks (vehicle routing). Perhaps, it is presumed that AVs are not different to other cars in vehicle routing. As noted before, connected-vehicle technology is an indispensable part of a working AV scheme. Such (real-time) communication data may result in collaboration between the AVs directionality capabilities, leading to more efficient and intelligent path-finding (or traffic flow).

Real-time data (including travel time and incidents) can be processed and analyzed centrally in order to calculate and direct (or advise) AVs towards the best possible route. Thus, more sophisticated and reliable vehicle routing models can be developed for which we use the term vehicle navigation in this manuscript. Moreover, we will propose a navigation model based on the concepts of system optimality [17, 18] which seeks the best possible traffic pattern (minimizing the total travel time in the system).

In the remainder of the article, Sect. 2 contains a brief history of AVs; Sect. 3 defines the level of automation; Sect. 4 presents the operational principals of AVs; Sect. 5 discusses sensors and monitoring technologies which are essential to data collection and real-time communication; Sect. 6 is dedicated to the advantages and disadvantages of AVs; and Sect. 7 is devoted to the navigation model of AVs. Concluding remarks are also provided in Sect. 7.

2 A brief history of autonomous vehicles

The first attempt towards driverless vehicles dates back as far as the early 1920s [19] and got momentum in the 1980s when researchers managed to develop automated highway systems [20, 21]. This paved the way for semiautonomous and autonomous vehicles to be connected to the highway infrastructure. Pioneer pilots of AVs were largely made in Germany and the U.S. during 1980 to 2000 [7, 22].

AVs are highly indebted to the extensive research on unmanned equipment made by the defense sector known as (DARPA) the U.S. Defense Advanced Research Projects Agency [23]. Google’s driverless car gave huge publicities to the AV and attracted a pool of talent from several disciplines. As recently as July 2015, Google’s driverless fleets logged over one million miles during which only 14 minor traffic accidents on public roads were recorded. In all cases, however, the AV was not at fault; rather, it was either being manually drivenFootnote 3 or the other driver was at fault [24]. Nevertheless, the first accident where the Google car was found at fault happened on Valentine’s Day 2016, when the car struck the side of a public bus in the Silicon Valley city of Mountain View [25].

3 Levels of automation

It is important to note that the level of automation can vary from zero to full automation. NHTSA classifies vehicle automation in five levels [26]:

  • No-Automation (Level 0) At all times, the driver has complete and sole command and control of the vehicle with respect to steering, braking, throttle and motive power.

  • Function-specific automation (Level 1) Some specific control function(s) such as electronic stability control or precharged brakes is(are) automated.

  • Combined function automation (Level 2) At least two main control functions such as adaptive cruise controlFootnote 4 in combination with lane centeringFootnote 5 are automated.

  • Limited self-driving automation (Level 3) Under certain traffic or environmental conditions, the driver cedes full control of all safety–critical functions and relies heavily on the vehicle to watch for any changes in conditions requiring transition to driver control. The driver will be required to resume control of the vehicle, but with sufficient transition time.

  • Full self-driving automation (Level 4) The vehicle is intelligently designed to monitor roadway conditions and act solo, performing all safety–critical driving functions for an entire trip (a fully driverless level).

4 How does the AV work?

Generally speaking, AVs operate on a three-phase design known as “sense-plan-act” which is the premise of many robotic systems [2729]. A substantial challenge for AVs rests in making sense of the complex and dynamic driving environment [1, 30]. To this end, the AVs are equipped with a variety of sensors, camera, radars, etc., which obtains raw data and information from the surrounding environment. These data would then serve as input for software which would recommend the appropriate courses of action, such as acceleration, lane changing, and overtaking.

A combination of surveillance technologies is employed to cope with such a challenging job [31]. Typically, this task is solved by a combination of radar, LidarFootnote 6, and mono or stereo camera systemsFootnote 7. In Appendix 1, we will briefly introduce the monitoring technologies in AVs [7, 32, 33, 34].

5 Advantages and disadvantages of AVs

Although transportation is a means to foster the prosperity of societies, it inevitably is coupled with negative externalities such as pollution, accidents, and human casualties. There are a large number of studies estimating these costs in terms of human-driven vehicles [35, 36]. These costs differ from direct costs incurred such as the cost of petrol, vehicle maintenance, vehicle registration, and licensing or public transport tickets. The externality cost is a hidden cost imposed on society as a whole; it includes costs such as traffic congestion, accidents and environment degradation, as well as security. In general, AV technology is largely perceived to have the potential to substantially abate (if not eliminate) many of these existing negative externalities. In one estimate, these external costs can be as high as the fuel price which is imposed on society as a whole, including low-income individuals who are solely reliant on public transport [7]. AVs can also create additional benefits such as increasing accessibility and mobility and even improving land use. Although there could be significant disadvantages associated with AVs, it is widely believed that these disadvantages are largely outweighed by the advantages. In the following section, we elaborate on the positives and negatives of AVs.

5.1 Safety and crashes

The statistics for road accidents in the United States in 2010 is shocking: 32,999 killed, 3.9 million injured, and 24 million vehicles damaged, the tangible and intangible costs of which total $277 billion [37]. This cost burden has a ripple effect, having an impact on productivity, medical costs, legal and court costs, workplace losses, emergency service costs, the congestion burden, insurance administration costs, and property damage. A downward trend in the number of crashes in the United States [38] is significantly indebted to the adoption of new technologies such as airbags, anti-lock brakes, electronic stability control,Footnote 8 head-protection side air bags, and forward collision warnings [39, 40]. These are features that will be adopted in AV technology. In particular, some studies estimate the reduction of crashes could be as high as one-third if all vehicles are equipped with adaptive headlights,Footnote 9 forward collisionFootnote 10 warnings, lane departure warningsFootnote 11, and blind spot assistanceFootnote 12 [39, 40, 41] which are attributed to Level 0 or Level 1 vehicle automation. Human error is blamed for more than ninety percent of crashes [42]. Therefore, AVs should be able to prevent an appreciable number of these crashes, in turn eliminating the vast majority of all traffic delays [7].

5.2 Congestion

Anderson et al. [7] have attributed three main factors related to AVs that affect congestion positively and sometimes negatively: (i) reducing traffic delay due to a reduction in vehicle crashes; (ii) enhancing vehicle throughput; and (iii) changes in the total vehicle-kilometer-traveled (VKT). An anticipated reduction in vehicle crashes would result in fewer delays and, in turn, higher reliability of the transport system. The changes in VKT due to the advent of the AV remain unclear, though some researchers hold the view that VKT in fact would increase (known as the “rebound effect”) [13]. For that, they speculate on a combination of factors such as additional VKT due to self-fueling and self-parking, increased use of AVs by those unable to driveFootnote 13, an increased number of trips (both unoccupied and occupied), a shift away from public transport and longer commutes [4345]. NHTSA came to the conclusion that the rebound rate will stabilize at 10 % [7].

The fact that AVs are connected may also provide an opportunity to mitigate the congestion burden. Dresner and Stone [46] propose a reservation-based system for alleviating traffic congestion, specifically at intersections when the vehicles are connected. The results show that the reservation-based system designed for connected AVs can perform two to three times better than traffic lights. As a result, it can smoothly handle much more congested traffic conditions. Dresner and Stone [47] show that as the number of AVs on the road increases, traffic delays decrease towards the levels exhibited in their previous work. A similar conclusion was drawn by Fajardo et al. [48].

Consequently, it is crystal clear that AV technology will soon have a positive effect on traffic congestion abatement unless it induces additional demand that in turn might add further burden to an already congested network. The overall impact of the AV on traffic congestion has yet to be investigated.

5.3 Taxi and car ownership

AV technologies can be conducive to driverless taxis or similar car-sharing schemes in which the cost of compensating cabdrivers’ time and talent is excluded. As a result, driverless cabs are expected to become cheaper and which eventually may discourage car ownership.

The concept of driverless taxis is analogous to car-sharing which is a thriving business model. AVs can boost car and ride sharing schemes as they can cater to multiple persons on demand [1]. Consequently, households may find driverless taxis more convenient and cheaper to hire than owning a vehicle. Furthermore, compared to car-sharing, driverless taxis should not be costlier. Given the fact that the driverless taxi obviates the need for annual fixed costs and maintenance normally associated with car-sharing as well as parking, it would provide even greater convenience. In actual fact, car-sharing has recently been found to lower VKT in the United States market [49]. Nevertheless, as previously mentioned, cheaper rides would be accompanied by new demands, especially from destitute (low-income) people who can now afford to either drive or to take a cab.

A recent analysis of US household data shows a significant reduction in vehicle ownership and an accompanying shift to vehicle sharing [50]. This reduction could be as high as 43 %—from 2.1 to 1.2 vehicles per household. Conversely, it is anticipated that this shift would inflate individual vehicle usage up to 75 %, from 11,661 to 20,406 miles per vehicle annually. (This increase in mileage does not factor in the additional miles generated during each “return-to-home” trip.)

All in all, AVs possess great potential to lower many costs associated with private modes as they are likely to instigate more trips, resulting in growth in VKT. AVs may also instigate an emergence in driverless taxis for which the ultimate effect on VKT is still unclear.

5.4 AV and electric vehicles

Environmental concerns, together with higher oil prices in the last decade have been the driving forces behind the emergence of Electric vehicle (EV) technology. The EV suffers from some operational drawbacks including a distance-traveling capacity limited to the size and durability of the batteries. It limits the EV to short-range travel and can make the process of finding charging stations a matter of constant anxiety [51].

In this context, one can find natural and organic synergy between shared AV fleets and EV technology: a fleet of AVs can resolve the practical limitations of EVs including travel range anxiety, access to charging infrastructure, and charging time management [52, 51].

Chen [53] has shown that fleet-managed AVs relieve such concerns based on real-time travel demand and established charging-station locations. Their financial analysis suggests that the combined cost of charging infrastructure, vehicle capital and maintenance, electricity, insurance, and registration for a fleet of AVs ranges from $0.42 to $0.49 per occupied mile traveled. Therefore, shared AV service can be offered at the equivalent per-mile cost of private vehicle ownership for low-mileage households. As such, automated electric cars will likely be competitive with current manually driven car-sharing services and significantly less expensive than on-demand driver-operated transportation services.

5.5 Roads’ capacity

AV technologies provide finely tuned acceleration-braking maneuvers at all times while constantly and tirelessly monitoring the surrounding traffic environment. Therefore, AVs are able to cruise at higher speeds while maintaining shorter distances (lower headways). Semiautonomous vehicles equipped with Adaptive Cruise Control (ACC) have already shown such a promising function [54]. Lower headways by a queue of AVs will not compromise safety, and hence, we are likely to see a platooning of AVs. As a result, the throughput of the roads (or capacity) will significantly increase—some studies have estimated by up to 5 times [55]. In some studies, the fact that AVs are connected has been exploited in signal control which has resulted in much less delay at signals or equivalently higher road capacity [4648].

5.6 Congestion pricing

As discussed earlier, the advanced technologies of AVs are supposed to provide an easing of traffic circulation and lowering of travel costs which in turn may induce additional travel demand. Such a demand can be seen as both a threat and an opportunity. The threat arises from the fact that the additional travel demand may worsen traffic congestion. The additional demand is the result of additional investment (AVs) injected into the transport system. Such concerns are becoming serious. For instance, researchers at Delft University in the Netherlands have advised the Dutch government to take measures (e.g., travel demand management) to curb the growth of travel and subsequent externalities of the impending AV technologies [56].

If one intends to maintain demand at the same levels as prior to the emergence of AVs, then there is a legitimate opportunity to tap into the induced demand by means of congestion pricing. The pricing can be set to the level at which the induced demand dissipates. Congestion pricing is currently an active area of research [57]. The high level of communication technologies among AVs can greatly streamline any sort of pricing schemes, such as distance-based charging and dynamic pricing schemes.

5.7 Value of time

AVs release drivers from engaging in the physical and mental actions associated with driving, allowing them to utilize this time on other productive activities en-route. As a result, AVs further reduce the opportunity cost of travel in terms of the saved value of time pertaining to off-wheel activities [7].

5.8 Land use

AVs may have a profound and prolonged impact on the land-use pattern. The value of land increases proportionally with its proximity to the central city where job opportunities exist in many industries such as banking, financial markets, and many other service areas. Proximity is manifested by transportation. The advent of automobiles in the beginning of the 20th century resulted in the emergence of suburbs. The relation between AVs and land use is both complicated and somehow paradoxical. In one scenario, the introduction of AVs could invigorate a trend towards even more dispersed and low-density land-use patterns surrounding metropolitan regions. In other words, AVs may result in the further growth of suburbs and may even push further into exurb areas. In the completely opposite scenario, AV technology obviates the acute need for parking spaces meaning parking space in the heart of cities can be freed up for other usage. Therefore, AVs could end up stimulating urban growth in central districts, adding to the density of CBDs. It is important to note that parking facilities monopolize a big chunk of space in CBDs. Shoup [58] estimated that the total area dedicated to parking space is on average equivalent to about 31 % of district areas.

In summary, the long-term expectation with the adoption of level 4 AVs is that one would likely see denser urban cores, more buildings and fewer parking spaces. At the same time, AVs could lead to even greater dispersion of low-density development in metropolitan fringe areas given the ability of owners to engage in other activities while vehicles pilot themselves [7].

5.9 Developing countries

Third world countries struggle with a lack of transportation infrastructure, such as roads, bridges, and public transport, which is impeding their economic development. Adoption of AVs by these developing countries may spare them the costs associated with expanding capital-intensive infrastructure. A similar paradigm was seen when developing countries leap-frogged over to mobile phone technology which exempted them from expensive landline infrastructure [7, 59].

5.10 Environment (energy and emission)

Anderson et al. [7] have pointed out three factors upon which the impact of AVs on the environment would be either positive or negative:

  • fuel efficiency of AVs,

  • carbon-intensity and life-cycle emissions of the fossil fuel used to power AVs, and

  • total change in VKT resulting from the use of AVs.

We have previously discussed VKT. In the next Section, we will elaborate on the fuel consumption and efficiency of AVs.

Regardless of the emergence of AVs, advances in vehicle design and engine efficiency have substantially decreased fuel consumption. In one estimation for passenger cars, fuel consumption was almost halved compared to the figures seen 30 years ago [60]. The adoption of AV technology even at Levels 1, 2, and 3 will lead to optimized driving and technology, also called eco-driving. Examples of some basic technologies that result in eco-driving are cruise control and smooth and gradual acceleration and deceleration. Eco-driving is proving to enhance fuel economy by 4 % to 10 % [61]. More optimistic predictions have envisaged an increase in fuel efficiency of up to 39 % [62]. We have also previously discussed that AVs may lead to a higher travel capacity and a reduction in fuel wastage during times of traffic congestion.

AVs also provide an opportunity for vehicles to communicate their maneuvers and actions with each other which may reduce idle time, improving both traffic and drive-cycle efficiencies [7]. Furthermore, a platoon of closely spaced AVs that stops or slows down less often will resemble a train. The result is expected to result in lower peak speeds (improving fuel economy) but higher effective speeds (improving travel time) [63, 64].

From a completely different perspective, the increased level of safety of AVs may lead to lightweight vehicles from car manufacturers. In fact, safety efforts are being directed towards accident avoidance and away from old-fashioned crashworthiness cars. Therefore, light vehicles are promising by-products of AV technology which in turn greatly contributes to less fuel consumption. For conventional vehicles, up to 20 % of the weight is attributed to safety-related features [61]. As an engineering rule-of-thumb, a 10-percent reduction in weight can lead to a 6- to 7-percent reduction in fuel consumption [7, 65, 66, 67]).

Turning to electric cars (from fossil-based cars) also brings added-value to fuel efficiency. It has been proven that the efficiency of the transformation in fossil-based cars versus electric cars is 1–3 [7].

5.11 Demand forecasting

As previously discussed, the implications and applications of AV technology are overshadowed by uncertainties. One key concern of car manufacturers, regulation authorities, and, to some extent, academic scholars is to forecast the future demand of AVs. A recent and comprehensive review on the subject was presented by Bansal and Kockelman [68]. These predictions were based on the extrapolation of trends derived from previous vehicle technologies, expert opinions, and forecasts of supply-side variables with very little emphasis on the underlying assumptions behind these predictions.

As noted earlier, [13] foresees 50 % of the worldwide car market being attributed to AVs by 2040. According to one estimate [69], the market share of Levels 2 and 3 automated vehicles will total some USD 87 billion. These estimations or predictions vary substantially. Other studies take a much more optimistic view on the matter [see the discussion provided by Bansal and Kockelman [68]].

It is safe to state that given the ongoing investment in AV technology by the giant car manufacturers, the car market could soon be supplied by first generation AVs. How large this move would be is difficult to predict; however, it is likely to be significant enough to warrant the undivided attention of those involved in the planning phase.

In the preceding section, we covered themes directly related to the transportation policies. The AV however has far-reaching implications. In Appendix 2, we discuss some additional advantages and disadvantages of AVs including machine ethics, cybersecurity, and laws and regulation.

6 AV navigation model

The navigation subject presented here is based on a macro view on how the AVs choose (or assign) routes. This subject differs from how an individual AV cruises through traffic by maneuvers, waving, acceleration/deceleration, etc., which is called “longitudinal control of an autonomous vehicle on the highway” (see Lefèvre et al. 2015. Autonomous car following: a learning-based approach, intelligent vehicles symposium (IV), 2015 IEEE. IEEE, pp. 920–926.). In such a domain, given a predefined route, the AV is closely controlled and driven through the traffic using learning-based methods which combine a driver model with model predictive control. The driver model generates accelerations/deceleration which replicates the behavior of a human driver. The use of the controller ensures that some predefined safety constraints are satisfied.

It is a matter of when AVs will be seen in the road network, and not if. Thus, they are an important part of transportation planning which requires the development of the appropriate models. The final stage of transportation modeling is the simulation of vehicle movements in the road network which is known as traffic assignment. To that end, there are two major simulations: micro and macro. In micro-simulation, detailed movements and behaviors of the individual vehicles are taken into account in any analysis. The early and basic features of automation (Levels 1 and 2) have prompted some scholars to include AV technologies into micro-simulations [7073]. As noted above, the connectedness of AVs has been investigated in signal control policies which resulted in significant reductions in delay [4648]. Other studies tend to extend the reach of the existing dynamic traffic assignment models to somehow include AVs [71, 74, 75]. Despite current computational technologies and current modeling knowledge, the scale of micro-simulation is limited to a portion of a city and not the entire city.

In contrast, macro-simulation easily encompasses large sized road networks. This section is devoted to a new macro-simulation to explicitly take a combination of AVs and non-AVs into consideration.

The fact that AVs must be connected—although this seems restrictive—can also be greatly exploited as an opportunity towards better vehicle routing. Vehicle routing refers to the way that vehicles seek their routes to get to their destinations. A common belief or model is based on the shortest path. In such a paradigm (also known as Wardropian principles), each vehicle “selfishly” chooses its own shortest possible path irrespective of other vehicles’ choices. This leads to an equilibrium condition called User Equilibrium (UE), a situation where no vehicle can unilaterally find a shorter path. This selfishness will likely result in final traffic patterns known as non-cooperative. Since vehicles have no knowledge of the other vehicles’ routes and destinations, the non-cooperative traffic pattern is the most widely recognized traffic model. In other words, when one is driving, he/she is completely unaware of neither where other vehicles are heading nor the routes that they are likely to take. In contrast, the cooperative traffic pattern assumes that the vehicles are aware of each other’s destinations and routes. It has been shown both theoretically and empirically that the cooperative traffic pattern is more desirable than the non-cooperative traffic pattern, possibly by a factor of 2 [76, 77]. It has also been shown that if a number of selfish cars were to collaborate, it may still result in a traffic pattern much superior to the selfish, non-cooperative pattern [7880].

The literature still needs to broach the topic of the manner in which AVs find their routes in the road network (vehicle routing). Perhaps, it is presumed that AVs are no different than other cars in vehicle routing, that is, the selfish (or non-cooperative) traffic pattern. Connected vehicles bring about critical real-time traffic data (such as travel time and incident reports) which can then be used in a cooperative traffic fashion. In doing so, AV data can then be compiled and processed in traffic monitoring centers that in turn will recommend the most appropriate routes. That is, each vehicle will now literally be aware of the routes and destinations of other vehicles. Therefore, a more sophisticated, efficient, and informed vehicle routing system is attained. We refer to this as vehicle navigation.

In transport terminology, the cooperative pattern is also referred to as “SO: System Optimal (or System Equilibrium)” versus the non-cooperative, referred to as “UE,” which are both the result of solving traffic assignment problems (TAP) [17, 18].

The complexity of the AVs’ navigation rests on the fact that the AVs must share road space with non-AVs, resulting in mixed traffic patterns. Consider for a moment two types of vehicles: non-AVs and AVs. The non-AVs maintain their selfish behavior since there is no leverage to force them to seek the non-shortest path. In the meantime, we have the capability to enforce a vehicle navigation plan on the AVs. The challenge now is to find a model for a mixed traffic pattern that consists of both SO and UE traffic patterns. In such traffic patterns, a fleet of AVs are connected and they cooperatively find their route (vehicle navigation), while others are selfish drivers who only seek the shortest possible paths (vehicle routing).

The advent of ITS which has led to advanced traveler information systems (ATIS) such as radio and variable message signs has seen real-time traveler information become a reality [81, 82]. As such, in the mid-1990s, some scholars proposed tapping into this source of information to push for cooperative routing [83]. Nevertheless, the idea has yet to become a reality as it continues to struggle with a number of issues such as (i) the lack of enforcement strategy; and (ii) issues related to the veracity and reliability of the information, as well as restricted penetration of the ATIS.

In the following expositions, we provide a mathematical formulation for the mixed SO-UE traffic pattern cast as a multiclass traffic assignment problem.

6.1 Vehicle navigation and routing formulations

In the following description, we refer to cooperative and non-cooperative cars as AVs and selfish cars, respectively. Consider \( G(N,\,A) \) a traffic network as a graph consisting of \( N,\,A \) sets of nodes and links, respectively, on which \( D \subset N \) is a set of destinations.

Since a set of roads are defined and based on nodes (i.e., \( A \subset N \times N\)), we represent roads using a single character \( a \in \,A \) as well as start and end nodes: \( a = ij = (i,j) \in \,A \). At equilibrium conditions, both UE and SO traffic arrive at a stable situation in which no car changes its route. For the UE part, let \( x_{a} \) denote a selfish traffic flow on road a while \( \bar{x}_{a} \) denotes the background traffic volume of the AVs on the respective road a. Therefore, the UE traffic pattern can be formulated as a non-linear programing problem [17, 18] as follows (throughout the manuscript, all terms are non-negative unless otherwise stated):

[UE-TAP]:

$$ \begin{aligned} &{\hbox{min} }\, {z(x) = \sum\limits_{a \in A} {\int_{0}^{{x_{a} }} {t_{a} (x_{a} + \bar{x}_{a} )\,{\text{d}}x} } } \\ & s.t. \\ \end{aligned}, $$
(1)
$$ \sum\limits_{p} {f_{p,i}^{k} = } q_{i}^{k} \quad i \in N,\,\,k \in D,$$
(2)
$$ f_{p,i}^{k} \ge 0 \quad p \in P_{i}^{k} ,\,i \in N,\,k \in D,$$
(3)
$$ x_{a}^{{}} = \sum\limits_{i} {\sum\limits_{k} {\sum\limits_{p} {f_{p,i}^{k} .\,\delta_{a,p,i}^{k} } } } \, \quad\,a \in A,p \in P_{i}^{k} ,\,i \in N,k \in D,$$
(4)

where z is the Beckmann objective function to be minimized; \( q_{i}^{k} \) is the selfish travel demand from i to k; \( f_{p,i}^{k} \) is the flow of selfish cars on path p from i to k; \( P_{i}^{k} \) is the set of all paths available to selfish cars from i to k; and \( \delta_{a,p,i}^{k} \) is the link-path incidence (1: if link a belongs to path \( p \) from i to k available to selfish cars, and 0 otherwise). Similarly at equilibrium, AVs volumes \( (\bar{x}_{a}^{{}} ) \) in the context of background traffic of selfish volume \( (x_{a}^{{}} ) \) can be formulated as follows [17, 18]:

[SO-TAP]:

$$ \begin{aligned} \begin{array}{*{20}c} {\hbox{min} } & {z(\bar{x}) = \sum\limits_{a \in A} {\bar{x}_{a} .\bar{t}_{a} (\bar{x}_{a} + x_{a} )} } \\ \end{array} \hfill \\ {\text{s}} . {\text{t}} .\hfill \\ \end{aligned}, $$
(5)
$$ \sum\limits_{p} {\bar{f}_{{\bar{p},i}}^{k} = } \bar{q}_{i}^{k} \quad i \in N,\,k \in D, $$
(6)
$$ \bar{f}_{{\bar{p},i}}^{k} \ge 0 \quad p \in P_{i}^{k} ,i \in N,\,k \in D,$$
(7)
$$ \bar{x}_{a}^{{}} = \sum\limits_{i} {\sum\limits_{k} {\sum\limits_{p} {f_{p,i}^{k} .\,\delta_{a,p,i}^{k} } } } \, \quad \,a \in A,p \in P_{i}^{k} ,i \in N,k \in D.$$
(8)

The notations are similar as the bar on top of the terms represents the AVs. Both AVs and selfish travel demand a share of the same network (\( a \in A\)). It is important to highlight the difference of the objective functions: while the UE-TAP is based on the Beckmann formulation (Eq. 1), the SO-TAP is based on the total travel time spent in the network (Eq. 5).

A plethora of methods have been proposed to solve the UE-TAP efficiently. As such, one easy way to solve a SO-TAP is to transform it to a UE-TAP. To do so, one simply needs to replace the delay function \( \bar{t}_{a} (\bar{x}_{a} + x_{a} )\) with the marginal delay function: \( \bar{t}_{a} (\bar{x}_{a} + x_{a} ) = \bar{x}_{a} .\,\,\partial \bar{t}_{a} (\bar{x}_{a} + x_{a} )/\partial \bar{x}_{a}\). Therefore, both UE-TAP and SO-TAP can be combined as a single UE-TAP but with two different delay functions and travel demand matrices. This approach is very common in transportation modeling and is known as a multiclass traffic assignment problem (MC-TAP). Solving a MC-TAP is computationally more intensive than a single class TAP for which a variety of methods such as Variational Inequality, Complementarity Method, Fixed-Points and Entropy Maximization, as well as origin-based (or bush based) methods have been proposed [8494].

The SO traffic pattern is the most desirable traffic pattern. In this pattern, the total travel time spent on the network (i.e., the network performance index) is minimized. In reality, people follow the shortest path which leads to the traffic pattern known as UE. In terms of the total travel time spent on the network (also an index for congestion levels), the gap between UE and SO can reach as high as 2.15. In other words, one can significantly improve the congestion level by up to 2.15 times by enforcing a SO pattern rather than a UE traffic pattern. This gap has been the motive for a variety of traffic management (or control) measures and policies such as parking planning, congestion pricing, and ramp metering. The advent of AVs can also be added to these schemes. In what follows, we elaborate on mixed SO-UE traffic flow using Braess’ famous network.

6.2 Mixed SO-UE traffic flow on Braess’ example

Braess [95] in his influential paper proved that adding more capacity to the road network (like constructing a new road) sometimes adversely worsens the traffic circulation, a phenomena coined after Braess as the Braess Paradox. Figure 3 shows a situation in which adding road 5 counter-expectedly deteriorates the current traffic flow.

Fig. 3
figure 3

Braess Paradox where removing link 5 yields a better traffic flow

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The occurrence of BP dwells right at the point that people follow UE rather than SO. Otherwise, no one would use road “5” provided in the network of Fig. 3b and hence no Braess paradox. In order to show the advantage of mixed SO and UE, we dispatch a portion of the travel demand of the above Braess network (Fig. 3) as AVs following SO. Given the delay functions provided in Fig. 3, the UE and SO traffic flows can be formulated as follows (note x and y represents UE and SO (or AVs) traffic volumes on the links):

UE flow:

$$ \hbox{min} \int_{0}^{{x_{1} }} {(50 + x_{1} + y_{1} )\,{\text{d}}x} + \int_{0}^{{x_{2} }} {(50 + x_{2} + y_{2} )\,{\text{d}}x} + \int_{0}^{{x_{3} }} {10 \cdot (x_{3} + y_{3} )\,{\text{d}}x + \int_{0}^{{x_{4} }} {10 \cdot (x_{4} + y_{4} )\,{\text{d}}x} } + \int_{0}^{{x_{5} }} {(10 + x_{5} + y_{5} )\,{\text{d}}x},$$
(9)
$$ x_{1} + x_{3} = (1 - \rho ) \cdot 6,$$
(10)
$$ x_{2} + x_{4} = (1 - \rho ) \cdot 6,$$
(11)
$$ x_{1} + x_{5} = x_{4},$$
(12)

SO flow:

$$ \begin{aligned} \hbox{min} \,\,(50 + x_{1} + y_{1} )y_{1} + (50 + x_{2} + y_{2} )y_{2} + 10 \cdot (x_{3} + y_{3} )y_{3} + 10 \cdot (x_{4} + y_{4} )y_{4} + (10 + x_{5} + y_{5} )y_{5} \hfill \\ \end{aligned}, $$
(13)
$$ y_{1} + y_{3} = \rho \cdot 6, $$
(14)
$$ y_{2} + y_{4} = \rho \cdot 6, $$
(15)
$$ y_{1} + y_{5} = y_{4},$$
(16)

where \( \rho ,\,\,0 \le \rho \le 1 \) is a parameter representing the share of AVs out of the total demand. The above problems can be combined to become a non-linear programing problem (NLP) as follows:

mixed UE-SO:

min (9) + (13), s.t. (10), (11), (12), (14), (15), (16).

The above NLP is encoded in GAMS [96] a leading optimization software. The GAMS code is made available in Fig. 4 to other scholars to be used in further studies.

Fig. 4
figure 4

GAMS code to solve mixed SO-UE traffic flow for Braess’ example

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We vary “rho” gradually from 0 [all UE, zero SO (AVs)] to 1 [zero UE, all SO(AVs)] to monitor the changes in the traffic flow when the share of SO increases. Table 1 presents the numerical results including UE and SO traffic volumes, whereas Table 2 provides travel times of the links as well as the total travel time in the network. It is obvious that as the share of SO (AVs) increases the total travel time (last column of Table 2) decreases until \( \rho = 0.5 \), at which the total travel time remains the same at 498. This can also be seen by tracking down the changes in \( x_{5} \) the traffic volume of link “5” which is a BP contaminated link. The value of \( x_{5} \) decreases to zero and remains steady from there as \( \rho \) decreases. In contrast, it is interesting to note that at any point of time (various values of \( \rho \)) the SO avoids the BP contaminated link “5”. Furthermore, from \( \rho = 0.5 \) onward, the UE traffic flow finds no incentive to drive through link “5” as a bypass road which is the result of the presence of SO in the network.

Table 1 Braess network example—mixed SO-UE traffic volume on the links
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Table 2 Braess network example—mixed SO-UE—travel time of the links and total travel time
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7 Conclusion

AVs have been an active area of research for some decades but particularly in the past five years. The recent joint efforts by universities and manufacturers have brought AVs to near readiness. AVs are believed to considerably lower transportation costs. In one estimate, social AV impacts in terms of crash savings, travel time reduction, fuel efficiency, and parking benefits may be as much as $2000 per annum per AV and may be as high as $4000 when comprehensive crash costs are accounted for [1]. The AV is still in the infancy stage. There is a considerable road to travel before maturity, implementation, and mass-market release are achieved.

The path is still problematic, facing several challenges. Perception of the environment remains the biggest challenge to reliable, smooth, and safe driving [7]. There is a long list of research questions covering a wide scope that will need to be addressed and answered, including but not limited to customer acceptance, societal impacts, communication technologies, ethical issues, planning, standards, and policy [7, 14]. Software challenges such as system security and integrity have also emerged as serious issues to be addressed. These in turn have a number of policy implications including the challenge for policymakers to streamline and regulate many diverse vehicles with different operating constraints. It is also of paramount importance for policymakers to ensure that drivers understand these vehicles’ capabilities and can operate them safely. One of the challenges ahead is to connect several intelligent vehicles to each other and to the infrastructure which gives rise to the application of Big Data, a topic concerned with the processing and analysis of large datasets [33]. In this paper, we shed light on transport related themes that are directly or indirectly and positively and negatively affected by emerging AV technology. Examples are land use, safety, vehicle-kilometer-traveled, parking, variation of demand, and fuel consumption. We have also highlighted the huge potential of incorporating connected vehicles into current traffic networks, resulting in more efficient and smooth traffic circulation. To this end, we put forward the concept of vehicle navigation to solve the routing problems faced by AVs when integrated with non-AVs. We then proceeded to formulate a traffic assignment model for the combination of AVs and non-AVs which is a synergy of system optimal and user equilibrium conditions.

As expected and shown using the Braess example, centrally dispatching, a fleet of vehicles (the AVs in this case) following the system-optimal pattern can indeed improve overall traffic flow. In theory, the improvements may be as high as 2.15 times, which is astonishing. This fact should not go unnoticed in modern traffic planning and management practices. Therefore, AVs and SO navigation is without doubt a worthy thread of research and practice for scholars and practitioners alike.

In the near future, AVs will be an indispensable part of modern transport systems [97]. Furthermore, in light of such rapid changes in intelligent transportation systems, the education system must without question, align itself with these emerging technologies. Traffic engineering schools must reform their curricula to ensure that they cover more diverse subjects including communication technologies, software development, electrical engineering, and environmental and energy sustainability [97].

This paper—for the first time—provides a methodological framework to concurrently model AVs navigation as a SO traffic pattern with UE traffic patterns of conventional vehicles (non-AVs). Numerical applications using methods such as Variational Inequality, Complementarity, or fixed point are worthy of far more investigation. Simultaneously, providing an agent-based micro-simulation formulation for the integration of AVs and non-AVs following the SO and UE principles should be the subject of further studies. Such agent-based modeling can then be utilized in real-time traffic management.