A Computationally Efﬁcient MPC for Green Light Optimal Speed

Advisory of Highly Automated Vehicles

Stephan Uebel

, Steffen Kutter

, Kevin Hipp

and Frank Schr

odel

Chair of Vehicle Mechatronics, Technische Universit

at Dresden, 01062 Dresden, Germany

Development Center Chemnitz/Stollberg, IAV GmbH, 09366 Stollberg, Germany

{Kevin.Hipp, Frank.Schroedel}@iav.de

Keywords:

Optimal Control, Sequential Quadratic Program, Velocity Control, Model Predictive Control, Green Light

Optimal Speed Advisory, Highly Automated Driving, V2X.

Abstract:

The current study introduces an approach for energy efﬁcient longitudinal vehicle guidance. The key idea is to

utilize a model predictive control (MPC) for the longitudinal vehicle dynamics which explicitly considers the

current and the predicted states of multiple trafﬁc lights ahead. Consequently, the vehicle can drive in urban

situations much more energy efﬁcient, which can be used to enlarge the range of electric vehicles or save

fuel while additionally improving travel time. Modern trafﬁc lights are equipped with transmitters that send

information about their actual and upcoming system states. Additionally, trafﬁc lights connected to a trafﬁc

control center can broadcast their future signal phases to vehicles many kilometers ahead. This information

may be used to adapt the vehicle speed so that engine operation points are optimal and stops can be avoided.

These kind of algorithms are referred to as green light optimal speed advisory. This work presents a novel

online capable MPC approach that uses a sequential quadratic program to solve the respective optimal control

problem. This approach is implemented in a framework introduced as well which allows driving tests in a real

vehicle.

1 INTRODUCTION

The term green light optimal speed advisory

(GLOSA) comprises all procedures for approaching

trafﬁc lights with vehicles in an optimal way by eval-

uating known or predicted information (trafﬁc light

phases). Corresponding assistance systems for pas-

senger car drivers are well studied (Schuricht et al.,

2011) and already available as prototypes today or

are even in regular operation in trams (Gassel et al.,

2012).

In order to overcome the computational burden

of the underlying optimal control problem, typically

simpliﬁed vehicle models and only few trafﬁc light

segments and phases (Erdmann, 2013) are taken into

account or sub-optimal, not online capable methods

like genetic algorithms (Seredynski et al., 2013) are

utilized.

A major drawback of the implementation in form

of a driver assistance system is the inclusion of the

human driver as the overall controller in the system,

since on the one hand there is an additional distraction

from the primary driving task (safety) and on the other

hand the driver’s control performance (accuracy and

speed) is poorer than technical systems.

With increasing vehicle automation the task of

optimally choosing the vehicle velocity with respect

to comfort, energy consumption and driving time is

therefore handed over to the highly automated driv-

ing system (HAD). The HAD combines both lateral

and longitudinal vehicle control with respect to the

detected surrounding trafﬁc situation and the planned

path of the ego vehicle.

The current study focuses on optimizing the vehi-

cle velocity in a HAD. Optimal velocity control has

already been applied to conventional vehicles. For in-

stance, an early implementation of real-time optimal

velocity control using dynamic programming (DP)

(Bellman, 1954) was presented by Porsche, called

ACC InnoDrive (Radke, 2013). Other approaches us-

ing DP concentrate on controlling velocity on short-

range trips, e.g. the distance between two trafﬁc lights

(Dib et al., 2011; Themann et al., 2014). Using DP

for both, velocity control and gear shifting of conven-

tional trucks, has been proposed in (Hellstr

om et al.,

2009; Hellstr

om et al., 2010). Furthermore, DP is

used for optimal velocity control of truck platoons

uhler, 2013), but there, for the sake of compu-

444

Uebel, S., Kutter, S., Hipp, K. and Schrödel, F.

A Computationally Efﬁcient MPC for Green Light Optimal Speed Advisory of Highly Automated Vehicles.

DOI: 10.5220/0007717304440451

In Proceedings of the 5th International Conference on Vehicle Technology and Intelligent Transport Systems (VEHITS 2019), pages 444-451

ISBN: 978-989-758-374-2

tational efﬁciency, gear, internal combustion engine

(ICE) on/off and travel time are removed from the

state vector, and the engine model is reduced to a

simple constant efﬁciency. Besides DP, other meth-

ods are examined for velocity control of conventional

vehicles. For instance, quadratic programming (QP)

(Boyd, 2004) has been proposed by (Gonsrang and

Kasper, 2015). Early research calculating the optimal

velocity of a conventional vehicle with Pontryagin’s

maximum principle (PMP) (Pontryagin et al., 1962)

was done by (Schwarzkopf and Leipnik, 1977). A

combination of QP and DP has been applied by (Mur-

govski et al., 2016) for optimal velocity control and

gear selection for a platoon of conventional vehicles.

Even the complex problem of computing the optimal

velocity of hybrid electric vehicle is solved by the au-

thors of (Uebel et al., 2018).

In contrast to the previous approaches mentioned,

this paper presents a novel algorithm combining op-

timal longitudinal control and GLOSA for multiple

trafﬁc lights and phases into one, online capable con-

trol structure for a HAD. The algorithm uses a se-

quential quadratic program (SQP) (Mikosch et al.,

2006, p. 529 ff.) to ﬁnd the optimal solution. The

close to optimal solution quality of this approach for

a more complex problem is shown in (Uebel, 2018),

by comparing the obtained results with the reference

solution, calculated with DP on a high performance

cluster at TU Dresden with over 8 months calculation

time. In result with assuming no costs for changing

gear, there is no deviation between the solutions but

the computational effort can be reduced to a millionth.

A case study for an implementation of the approach in

a Volkswagen Golf passenger car is presented which

shows the capability of the algorithm to compute the

optimal trajectories for the velocity implemented at an

online platform under real world driving conditions.

This paper is organized as follows. Section 2 in-

troduces all model equations leading to the descrip-

tion of the discrete optimal control problem (OCP).

Section 3 describes model abstractions that reduce the

computation time for the SQP. Afterwards, it is shown

how the SQP is used to solve the GLOSA problem.

Finally, a case study is performed and discussed.

2 PROBLEM DESCRIPTION

In this section, the GLOSA problem is formulated.

First a vehicle model is introduced which is used to

derive an OCP afterwards.

2.1 Vehicle Model

The powertrain of the model includes an internal com-

bustion engine (ICE) that converts chemical fuel en-

ergy to mechanical propulsion energy. The rotational

speed of the ICE

ω(v, g) =

γ(g) (1)

depends on the longitudinal vehicle velocity v, the dy-

namic rolling radius of the wheels r and the gear ratio

γ(g). Note, that g is not a control signal here because

the gear yielding the lowest fuel consumption is se-

lected at any instant (cf. 3.1).

The control signals are the ICE force F

= T

and the mechanical brake force F

. They are gathered

in the vector of inputs

u = (F

). (2)

The force F

is translated by the gearbox to a

wheel force. The gearbox has an efﬁciency η

that

determines its dissipative force

T,d

(u) =

(

(η

− 1)/η

, for F

≤ 0

(1 − η

), for F

> 0

(3)

which counteracts the wheel force. The brake and the

driving resistance due to inertia, air drag and road

slope cause further counteracting forces. Accord-

ingly, the balance of forces at the wheel is

+ c

+ F

= (F

− F

T,d

(u))γ(g),

∀s ∈ [s

(4)

where m is the vehicle mass, c

is a constant for the air

drag and c

a slope-dependent disturbance that com-

bines the rolling resistance and the force due to road

gradient. The balance is formulated in a space coor-

dinate s which denotes the travelled distance starting

from an initial position s

to a ﬁnal position s

. The

term vdv/ds in (4) derives directly from the time to

space transformation

= v

. (5)

Note that, for brevity, the dependency on s is not dis-

played. All states and control signals and some coef-

ﬁcients in this paper depend on s. Constants that do

not depend on s are displayed in upright letters. For

instance in (4), c

does not depend on s while c

does.

It can be noticed that the state dynamics in (4) are

nonlinear. A straightforward way to remove nonlin-

earity, without introducing approximations, is to per-

form a variable change, where kinetic energy

(6)

A Computationally Efﬁcient MPC for Green Light Optimal Speed Advisory of Highly Automated Vehicles

445

is used as system state instead of longitudinal veloc-

ity. In space domain, the derivative of vehicle energy

transforms into

∂E

∂s

= E

= mv

= mvv

, (7)

where the prime symbol (

) is used as a shorthand

notation for the ﬁrst derivative with respect to s. As a

consequence of (7), (4) can be written as

= f

(u,E

) =

− F

T,d

(u))γ(g) − F

− 2c

/m − c

∈ m[a

min

max

(8)

which gives the state differential equation of the ki-

netic energy f

that is limited by the minimum ac-

celeration a

min

and the maximum acceleration a

max

introduced to ensure driver comfort.

Since the problem is formulated in space coordi-

nates, the travel time t becomes a system state. Its

dynamics are expressed by

= 1/v = 1/

/m = f

). (9)

The system states are gathered in the complete state

vector

x = (x

). (10)

2.2 Problem Formulation

This section formulates the OCP in discrete space us-

ing the previously introduced model, where k is the

discrete index for the position. The same symbols that

were used in the continuous time representation, are

used in this section to denote discrete signals.

The main objective is to minimize the monetary

costs for a given route, subject to state and control

constraints. The costs are expressed as the consumed

fuel energy over the horizon multiplied by the respec-

tive price κ

. The fuel energy is the product of the

sample length ∆s(k) and the sum of F

and the dissi-

pative ICE force F

E,d

,x), which is provided by a

lookup table.

The ensued OCP,

minimizeJ (u(k), x(k),k) (11a)

= κ

∑

k=1

(k) + F

E,d

(k), x(k))γ(g(k))∆s(k)

subject to

x(k + 1) = x(k) + f(u(k),x(k),k)∆s(k), (11b)

x(1) = x

, (11c)

(k) ∈ m[a

min

max

], (11d)

x ∈ [x

min

(k), x

max

(k)], (11e)

u ∈ [u

min

(x(k)),u

max

(x(k))], (11f)

contains the function

f(u(k),x(k),k) = ( f

(k), f

(k)) (12)

which combines the state dynamics of the states. The

initial state conditions are given by the vectors x

and

the state space of the OCP (11) is bounded by lower

min

(k)) and upper (x

max

(k)) limits.

2.3 Velocity and Time Boundaries

An example for the boundaries on kinetic energy de-

pitcs Figure 1, where the upper limit is obtained by

100

0 1 2 3 4 5 6 7 8

Position (km)

Velocity (km/h)

Figure 1: Boundaries to the velocity (kinetic energy). The

red line represents the legal speed limit, while the blue line

depicts limits due to a maximum cornering speed. The

green line is the lower speed limit.

considering legal speed limits (red line). Addition-

ally, demands on comfort (Bellem et al., 2016), (Rey-

mond et al., 2001), (Scherer et al., 2015) as well

as existing standards (International Organization for

Standardization, 2009) limit the longitudinal and lat-

eral acceleration, which lowers the maximum veloc-

ity (blue line). The lower bound on the velocity is

obtained by subtracting a constant value from the up-

per speed limit (green trajectory). This value is in-

ﬂuenced by the surrounding trafﬁc, e.g. if the value

is selected too high, the vehicle might be an obstacle.

However, when approaching intersections and trafﬁc

lights lower velocities are accepted (green semicolon

velocity) to enable a stop of the vehicle.

It can be understood that the time is bounded by

the bounds on E

. For example, the shortest time to

a position can be derived following the upper limit

on E

(highest velocity). Additionally, the time is

bounded by the timing of the trafﬁc lights phases,

which is illustrated in the upper plots of Figure 4 and

5 in the results section.

2.4 ACC and Stop-line Functions

Solving problem (11) purely in a MPC is not suf-

ﬁcient to implement a longitudinal velocity control

VEHITS 2019 - 5th International Conference on Vehicle Technology and Intelligent Transport Systems

446

under real conditions (cf. Section 4). For example

slower vehicles driving ahead on the same lane are

neglected by the OCP. However, the solution of the

OCP (11) can be used as a set velocity for a controller

that works as a typical ACC when approaching a ve-

hicle or can assure stopping at the stop line of a red

trafﬁc light.

Therefore, an algorithm solving (11) is utilized for

the calculation of the optimal velocity with a long pre-

diction horizon and explicit consideration of trafﬁc

lights. The computed target set is used for a shorter

horizon by a lower level which contains an ACC and

a stop-line approaching function.

A modular control design realizes both functions,

which is a straightforward way of changing between

different control modes. Following, three common

modes are listed.

• Speed-based longitudinal dynamic control: The

controller follows a given velocity which is ob-

tained from the OCP algorithm. The controller

structure corresponds to a conventional cruise

control.

• Object-based longitudinal dynamic control: The

controller uses sensor data to take vehicles driving

ahead and other objects into account. The con-

troller structure corresponds to a classic ACC.

• Trajectory-based longitudinal dynamic control:

This mode realizes an accurate longitudinal dy-

namic trajectory tracking without imposing an ad-

ditional dynamic on the system. In this controller

mode, high requirements with regard to follow a

given velocity trajectory (e.g. to brake at a stop

line) must be realized in order to ensure driving

comfort and safety to other road users.

In order to react to slower road participants driv-

ing ahead, the ACC reduces the desired speed, com-

puted by the OCP algorithm. In detail, the distance

to the vehicle ahead is controlled in an outer-control

loop, which results in a new set speed for the vehicle,

while the desired speed is controlled within the inner-

control loop. In the current set up of the test vehicle,

an acceleration instead of a velocity interface is used

for the longitudinal guidance. Therefore, the chosen

acceleration set point is transmitted to the acceleration

controller, which computes the corespondent engine

and brake torques.

Because of a higher update time the OCP algo-

rithm cannot guarantee a stop at the precise position

of the stop line. Due to this a trajectory-based longi-

tudinal controller is used for stopping the vehicle. It

activates if the velocity drops below a speciﬁc vehicle

speed (e.g. 10 km/h) and uses an extra front camera

and corresponding algorithms to determine the cor-

rect position of the stop line. This position is used to

calculate a precise breaking trajectory.

3 GLOSA COMPUTATION

It is not straightforward to regard a set of time con-

straints which are imposed by the phases of a trafﬁc

light with the OCP formulated in the previous sec-

tion. The reason is that the OCP formulation (11)

allows only one value for the lower and one for the

upper time boundary (cf. (11e)) at each instant (po-

sition) while several lower and upper boundaries are

necessary to consider the phases of the trafﬁc lights.

Consequently, to ﬁnd the optimal solution for the

GLOSA problem the OCP has to be computed sev-

eral time with different values for the time constraints

at each computation. Consequently, in order to solve

the GLOSA problem online, this section formulates

the OCP as an SQP scheme, for which there are com-

putationally efﬁcient solvers.

3.1 Approximated Objective

Following, several steps are proposed to adapt the

model in order to incorporate a fast solver

that de-

creases the computational demand, including abstrac-

tion of the engine transmission unit and a conservative

QP modeling for an SQP scheme.

As stated before gear shifts are assumed to be in-

stantaneous and the gears are optimized in advance,

by preselecting gears that minimize fuel consumption

when the ICE is propelling the vehicle. Thus, instead

of investigating the fuel consumption map on the en-

gine side, a corresponding fuel consumption map is

generated for the engine transmission unit which pro-

vides the force

E,W

to the wheel. As there is a redun-

dancy, in the sense that different gears may provide

the same force-speed points, it is possible to chose op-

timal gears that minimize fuel consumption for each

operating point. The obtained fuel consumption map

is then approximated by the following analytic ex-

pression

= ζ

(ζ

+ζ

E,W

+ζ

E,W

+ζ

(13)

The over-line symbol tilde (

{·}) is used to denote ap-

proximated signals of the SQP.

The objective of the SQP is to minimize the mon-

etary costs

ECOS presented in (Domahidi et al., 2013) is used.

A Computationally Efﬁcient MPC for Green Light Optimal Speed Advisory of Highly Automated Vehicles

447

E,W

) = κ

= κ

(

−

)) + κ

ds +κ

+ κ



+ ζ

E,W

+ ζ

E,W

+ ζ



= κ

(

−

)) + κ

(

t(s

) −

) + κ

− s

)

+ κ



+ ζ

E,W

+ ζ

E,W

+ ζ



(14)

which is a quadratic convex function. The terms in-

cluding t

as well as the term multiplied by ζ

are con-

stants that can be removed from the objective, without

affecting the optimal solution. The objective can then

be written in a discrete form, as discussed in Section

2.2.

3.2 Approximated Constraints

The maximum force that the engine-transmission unit

can deliver is illustrated in Figure 2. It can be ob-

served that the force limit is a highly nonlinear and

partly discrete function. To remove the need for in-

teger decisions, a piecewise nonlinear inner approxi-

mation is performed, of the form

E,Wmax

= min





W,1

+ ζ

W,2

W,3

W,4

+ ζ

W,5





. (15)

The inner approximation ensures that a solution ob-

tained by solving the approximated problem is feasi-

ble also in the original problem. It can be observed

in Figure 2 that the force limit, left of the peak point,

is a concave function. A concave function can be ap-

proximated with a negligible error by expressing it as

the minimum of sufﬁciently many afﬁne pieces. Only

two such pieces have been used here (the ﬁrst two in

(15)). Finally, the last, nonlinear piece in (15) is cho-

sen to capture the power limit of the engine, as it is an

alternative expression of an inverse speed relation.

0 50 100 150

v (km/h)

100

Normalized

E,Wmax

(%)

0 0.5 1 1.5 2

(MJ)

Original

Approximated

Figure 2: Approximated maximum force of the engine-

transmission unit over velocity (left) and over kinetic energy

(right) compared to the original model.

The nonlinear time dynamics,

= 1/

/m (16)

cannot be expressed as a quadratic function and are

therefore approximated using a reference kinetic en-

ergy,

, about which linearizations are performed;

further discussed below.

The obtained optimization problem has now linear

dynamics

= −

(17a)

E,W

−

− 2c

/m − c

(17b)

= 1/

/m (17c)

but nonlinear and non-convex constraints, due to the

nonlinear term 1/

in the force limits of the

engine-transmission, (15). Due to the sign of the co-

efﬁcients multiplying 1/

, it can be observed that

this term is convex. Therefore, linearizing it about the

reference trajectory

≈ f

lin

(

) (18)

provides a convex inner approximation. This is the

ﬁnal ingredient for developing a computationally efﬁ-

cient SQP.

3.3 Approximated Problem

Formulation

By deﬁning the state and control vectors as

x = (

t),

u = (

E,W

M,W

) (19)

and by discretizing with, e.g., zero-order hold, the re-

sulting QP solved in each iteration of the SQP can be

summarized as

minimizeJ(

k),

k)) + Q(

k),

k)) (20a)

subject to

k + 1) = A

k) + B

k) + w(

k) (20b)

k) + D

k) ≤ b(

k) (20c)

k) ∈ [

min

(

k),

max

(

k)] (20d)

k) ∈ [

min

(

k),

max

(

k)] (20e)

x(0) =

t(N

) <=

(20f)

(20g)

where the matrices A

A, B

B, C

C, D

D and the vectors w, b,

min

max

, can be found from eqs. (15) and (17). Note

that these matrices and vectors depend on

k since the

slope as well as the boundaries on

and the

t as

well as the approximation of t

depend on the posi-

tion. The distance between two samples

k might be

VEHITS 2019 - 5th International Conference on Vehicle Technology and Intelligent Transport Systems

448

varying depending on the boundaries on

, i.e. at

high velocities the sampling can be sparser.

The term Q in the objective is a standard term in

the SQP framework that provides additional search

direction towards the optimal solution that also min-

imizes the linearization error. It includes Hessian of

the Lagrangian and Jacobian of the objective function,

with respect to

. For further details, see (Mikosch

et al., 2006). After each QP iteration, the trajectory

about which the problem is linearized (

) is updated

by moving towards the direction of the current opti-

mal solution. Thus,

is updated as

i+1

+ ξ(

i∗

−

) (21)

where i is the current iteration, ∗ is the optimal so-

lution in the current iteration and ξ is the step size

that regulates the convergence rate. A high step size,

ξ = 1, has been chosen for this problem. The initial

trajectory

is selected as the mean between the up-

per and lower velocity boundaries.

4 CASE STUDY

This section presents a case study of the GLOSA ap-

proach. Before results for two different trafﬁc light

timings are shown, the test arrangement is presented.

4.1 Framework

The HAD framework depicted in Figure 3 consists of

three layers which is similar to classic robotic solu-

tions.

The ﬁrst layer realizes the environment perception

with the main focus on object detection and predic-

tion as well as on lane detection and free space cal-

culation. The second layer consist of decision mak-

ing, including strategic, tactical and operational plan-

ing. The strategy module realizes route calculation

and abstract mission planning. It derives prioritized

missions and a route enhanced by abstract action re-

quests. Therefore, it optimizes the whole route of the

vehicle with respect to driving time, comfort and mis-

sion fulﬁllment.

The tactical module aims to generate optimal driv-

ing maneuver requests (e.g. lane change, lane keep-

ing, parking) in order to follow the strategic route

and actions. It continuously checks the driving state

against the target state (e.g. target speed and target

lane) and attempts to optimize the short term travel-

ing behavior.

The operational module supplies atomic driving

maneuvers such as lane keeping, lane change, etc.

This lowest decision level knows the feasibility of

each individual driving maneuver and tries to fulﬁll

the requirements of the tactical level by using path

planning algorithms. Below the decision layer, the

trajectory planing and lateral and longitudinal vehi-

cle dynamic controllers realize the detailed movement

planing and tracing task in side the third layer.

4.2 Vehicle

The test vehicle which is used in the current study, is

a VW Golf VII which is equipped with computation

hardware (a dSPACE MicroAutoBox II and an indus-

try PC).

4.3 Route

A test track near the airﬁeld of the city of Dresden in

Saxony/Germany was selected which is about 6.6 km

long and equipped with four trafﬁc lights. For future

real driving tests these trafﬁc lights are equipped with

communication hardware in order to send the planned

trafﬁc light phases to the test vehicle.

4.4 Results

The longitudinal control of the approach is evaluated

in two simulations: First, a simulation of the test track

is performed where measured trafﬁc light timings are

used, to show the general capability of the algorithm

to ﬁnd the optimal speed through green phases of sev-

eral trafﬁc lights. For the second simulation the tim-

ing is changed, so the vehicle has to stop at the third

trafﬁc light.

The results of the two simulations are shown in

the Figures 4 and 5, where the top plots shows the

timing of the trafﬁc light phases over the position.

Additionally, the bound on the time derived from the

minimum velocity is shown by the dotted line. It can

be observed in both ﬁgures that following the mini-

mum velocity would cause driving through a red light

phase of the second trafﬁc light. Due to this, the ap-

proach decreases the velocity yielding the one shown

with the time trajectory depicted with a solid line in

the upper plots.

The bottom plots show the associated velocity tra-

jectories with solid lines, as well. The planned bounds

on the velocity are shown with dotted lines. In or-

der to avoid driving through red light, the minimum

velocity has to be adapted which is done in the ﬁrst

half of the route. However, adaption is only allowed

to about 60 % of the maximum velocity. Even with

adaption of the velocity it is not possible to reach a

A Computationally Efﬁcient MPC for Green Light Optimal Speed Advisory of Highly Automated Vehicles

449

Figure 3: Functional Architecture for HAD System.

100

Time (s)

0 500 1000 1500 2000

Position (m)

Velocity(km/h)

Figure 4: Results of the ﬁrst simulation. The top plot shows

the phase timing of the trafﬁc lights and the time trajectory

yielded by the algorithm, while the bottom plot depicts the

associated velocity trajectory of the vehicle. The planned

lower state bound for the velocity (lower dotted line) is vio-

lated at some instances in order to reach the green phase of

the next trafﬁc light.

Time (s)

0 200 400 600 800 1000 1200

Position (m)

Velocity (km/h)

Figure 5: Results of the second simulation where a stop at

the third trafﬁc light is inevitable. In contrast to the ﬁrst

simulation, the vehicle accelerates to the minimum velocity

before braking at the third trafﬁc light.

green phase of the third trafﬁc light in the second sim-

ulation shown in Figure 5. Consequently, the algo-

rithm accelerates to the minimum velocity and brakes

before the third trafﬁc light. In order not be an obsta-

cle for other road participants, the algorithm is con-

ﬁgured to avoid a slow deceleration after the second

trafﬁc light which would be energy efﬁcient. The ma-

jor part of road users does not accept driving less than

the minimum velocity shown in Figures 4 and 5 even

when approaching a red light as we experienced in

real world testing.

5 CONCLUSIONS

The simulations show that the introduced novel MPC

algorithm for GLOSA which solves a set of OCPs

using an SQP scheme is suitable for real driving

tests. Performing these tests will be the next step.

Therefore, the algorithm is already successfully im-

plemented to the HAD framework presented in this

paper where it performed with a turnaround time of

about 0.2 s. The main challenge is to obtain a predic-

tion of the trafﬁc light phase timings with a sufﬁcient

horizon length since their signals are trafﬁc-actuated.

ACKNOWLEDGEMENTS

The research shown here is related to the project

initiative ”Syncronized Mobility 2023” and part of

the projects ”REMAS”, ”SYNCAR” and ”Harmo-

nizeDD” which are publicly funded by the European

Union and the Federal Ministry of Transport and Dig-

ital Infrastructure in Germany. Additionally, the au-

thors would like to thank The Center for Information

Services and High Performance Computing (ZIH) at

Technische Universit

at Dresden.

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A Computationally Efﬁcient MPC for Green Light Optimal Speed Advisory of Highly Automated Vehicles

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