Microscopic traffic flow model

Microscopic traffic flow models are a class of scientific models of vehicular traffic dynamics.

In contrast, to macroscopic models, microscopic traffic flow models simulate single vehicle-driver units, so the dynamic variables of the models represent microscopic properties like the position and velocity of single vehicles.

Car-following models edit

Also known as time-continuous models, all car-following models have in common that they are defined by ordinary differential equations describing the complete dynamics of the vehicles' positions $x_{\alpha }$ and velocities $v_{\alpha }$ . It is assumed that the input stimuli of the drivers are restricted to their own velocity $v_{\alpha }$ , the net distance (bumper-to-bumper distance) $s_{\alpha }=x_{\alpha -1}-x_{\alpha }-\ell _{\alpha -1}$ to the leading vehicle $\alpha -1$ (where $\ell _{\alpha -1}$ denotes the vehicle length), and the velocity $v_{\alpha -1}$ of the leading vehicle. The equation of motion of each vehicle is characterized by an acceleration function that depends on those input stimuli:

{\ddot {x}}_{\alpha }(t)={\dot {v}}_{\alpha }(t)=F(v_{\alpha }(t),s_{\alpha }(t),v_{\alpha -1}(t),s_{\alpha -1}(t))

In general, the driving behavior of a single driver-vehicle unit $\alpha$ might not merely depend on the immediate leader $\alpha -1$ but on the $n_{a}$ vehicles in front. The equation of motion in this more generalized form reads:

{\dot {v}}_{\alpha }(t)=f(x_{\alpha }(t),v_{\alpha }(t),x_{\alpha -1}(t),v_{\alpha -1}(t),\ldots ,x_{\alpha -n_{a}}(t),v_{\alpha -n_{a}}(t))

Examples of car-following models edit

Optimal velocity model (OVM)
Velocity difference model (VDIFF)
Wiedemann model (1974)
Gipps' model (Gipps, 1981)^[1]
Intelligent driver model (IDM, 1999)^[2]
DNN based anticipatory driving model (DDS, 2021)^[3]

Cellular automaton models edit

Cellular automaton (CA) models use integer variables to describe the dynamical properties of the system. The road is divided into sections of a certain length $\Delta x$ and the time is discretized to steps of $\Delta t$ . Each road section can either be occupied by a vehicle or empty and the dynamics are given by updated rules of the form:

v_{\alpha }^{t+1}=f(s_{\alpha }^{t},v_{\alpha }^{t},v_{\alpha -1}^{t},\ldots )

x_{\alpha }^{t+1}=x_{\alpha }^{t}+v_{\alpha }^{t+1}\Delta t

(the simulation time $t$ is measured in units of $\Delta t$ and the vehicle positions $x_{\alpha }$ in units of $\Delta x$ ).

The time scale is typically given by the reaction time of a human driver, $\Delta t=1{\text{s}}$ . With $\Delta t$ fixed, the length of the road sections determines the granularity of the model. At a complete standstill, the average road length occupied by one vehicle is approximately 7.5 meters. Setting $\Delta x$ to this value leads to a model where one vehicle always occupies exactly one section of the road and a velocity of 5 corresponds to $5\Delta x/\Delta t=135{\text{km/h}}$ , which is then set to be the maximum velocity a driver wants to drive at. However, in such a model, the smallest possible acceleration would be $\Delta x/(\Delta t)^{2}=7.5{\text{m}}/{\text{s}}^{2}$ which is unrealistic. Therefore, many modern CA models use a finer spatial discretization, for example $\Delta x=1.5{\text{m}}$ , leading to a smallest possible acceleration of $1.5{\text{m}}/{\text{s}}^{2}$ .

Although cellular automaton models lack the accuracy of the time-continuous car-following models, they still have the ability to reproduce a wide range of traffic phenomena. Due to the simplicity of the models, they are numerically very efficient and can be used to simulate large road networks in real-time or even faster.

Examples of cellular automaton models edit

References edit

^ Gipps, P. G. (1981). "A behavioural car-following model for computer simulation". Transportation Research Part B: Methodological. 15 (2): 105–111. doi:10.1016/0191-2615(81)90037-0. ISSN 0191-2615. Retrieved 2022-02-17.
^ Treiber, null; Hennecke, null; Helbing, null (August 2000). "Congested traffic states in empirical observations and microscopic simulations". Physical Review E. 62 (2 Pt A): 1805–1824. arXiv:cond-mat/0002177. Bibcode:2000PhRvE..62.1805T. doi:10.1103/physreve.62.1805. ISSN 1063-651X. PMID 11088643. S2CID 1100293.
^ Isha, Most. Kaniz Fatema; Shawon, Md. Nazirul Hasan; Shamim, Md.; Shakib, Md. Nazmus; Hashem, M.M.A.; Kamal, M.A.S. (July 2021). "A DNN Based Driving Scheme for Anticipatory Car Following Using Road-Speed Profile". 2021 IEEE Intelligent Vehicles Symposium (IV). 2021 IEEE Intelligent Vehicles Symposium (IV). pp. 496–501. doi:10.1109/IV48863.2021.9575314.

[1] Gipps, P. G. (1981). "A behavioural car-following model for computer simulation". Transportation Research Part B: Methodological. 15 (2): 105–111. doi:10.1016/0191-2615(81)90037-0. ISSN 0191-2615. Retrieved 2022-02-17.

[2] Treiber, null; Hennecke, null; Helbing, null (August 2000). "Congested traffic states in empirical observations and microscopic simulations". Physical Review E. 62 (2 Pt A): 1805–1824. arXiv:cond-mat/0002177. Bibcode:2000PhRvE..62.1805T. doi:10.1103/physreve.62.1805. ISSN 1063-651X. PMID 11088643. S2CID 1100293.

[3] Isha, Most. Kaniz Fatema; Shawon, Md. Nazirul Hasan; Shamim, Md.; Shakib, Md. Nazmus; Hashem, M.M.A.; Kamal, M.A.S. (July 2021). "A DNN Based Driving Scheme for Anticipatory Car Following Using Road-Speed Profile". 2021 IEEE Intelligent Vehicles Symposium (IV). 2021 IEEE Intelligent Vehicles Symposium (IV). pp. 496–501. doi:10.1109/IV48863.2021.9575314.

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