WO1998008207A1 - Method and equipment for motorway control - Google Patents
Method and equipment for motorway control Download PDFInfo
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- WO1998008207A1 WO1998008207A1 PCT/SE1997/001331 SE9701331W WO9808207A1 WO 1998008207 A1 WO1998008207 A1 WO 1998008207A1 SE 9701331 W SE9701331 W SE 9701331W WO 9808207 A1 WO9808207 A1 WO 9808207A1
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- access
- cars
- motorway
- information
- traffic
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- 238000000034 method Methods 0.000 title claims abstract description 94
- 238000009941 weaving Methods 0.000 claims abstract description 110
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Classifications
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- G—PHYSICS
- G08—SIGNALLING
- G08G—TRAFFIC CONTROL SYSTEMS
- G08G1/00—Traffic control systems for road vehicles
- G08G1/07—Controlling traffic signals
- G08G1/075—Ramp control
Definitions
- SCA system controlled access
- the system controlled access is designed by several coordinated steps. Actions are taken at the road net on different distances from the given access point.
- traffic control actions are introduced, that e g might limit average flows in to SCA, i e for an average time period, some minutes or less, a controlled amount of cars will arrive.
- those cars During the travel towards the motorway access, those cars however might pack together to various dense "car- packets", which implies that during short time periods of less than a minute, large differences from the average flow might arise.
- Those differences have to be considered at e g closer positioned accesses, not allowing many cars at the access at the same time as there are a package of dense traffic on the motorway. Otherwise all the cars haven't space enough for weaving, and the traffic collapses resulting in queue build up and high risk for accidents.
- the invention can be regarded as a system of actions on four different levels.
- the first level is
- Access control along a motorway and is based on traffic management of a road-network, considering various access roads, as other motorways, connections to city street-network etc.
- the second level is "preparatory weaving", which is performed on the motorway upstream exits and access-roads.
- the third level is "preparatory actions", which are performed just before the "ramp”.
- the fourth level is the "local level" at the position of the ramp.
- the four levels can work together and combine to an efficient and safe access traffic. But compared to to-day situation, every level by itself can be implemented resulting in improved access control.
- the invention concerns a system-based improvement of access traffic control, where the different levels can be implemented one by itself, or in combinations to various extent, or successively at different occasions, possibly as steps in a planned expansion, or within a given short time period to obtain a more direct cooperation of the applied levels.
- the most used on-flow "control” is free weaving of traffic from the access road into the motorway, but with certain rules giving the motorway traffic priority, i e the cars from the access-road should adapt and weave into the gaps between the cars of the motorway.
- the traffic flow on the motorway is close to its maximum, there aren't enough safety margins to put cars into the small existing gaps. If a car anyhow turns into such a gap, the driver wants to start braking to increase the distance to the car in front of him.
- ramp-mete ⁇ ng The concept of ramp-mete ⁇ ng is often described as a way to limit the access flow to the ramp, not allowing more vehicles to enter than what gap space there are on the motorway.
- more cars can be allowed to access, and if it is very dense traffic on the motorway, no cars are allowed and so on.
- the access is regulated by traffic signals If there are too many cars in a row on the access road, they will be lined up in queue, and one car a time is allowed, when the traffic light signal turns green for some second.
- the other problem is that the light signal has to be positioned far upstream on the access road, giving the stopped cars a long enough distance of acceleration to reach the speed ( 1 10 km/h ) of the motorway traffic.
- the present invention has another function and is primarily created for driver-controlled cars So the inherent functions are open for differencies in driver behaviours, and takes into account the natural statistical variations in traffic
- the basic parts of the invention can be applied with to-day cars, and is not requiring the advanced vehicle systems and methods, which are needed for the ideas of "car-trains"
- the described access control is treating situations, when the flow of the motorway and the access road together is low enough giving a total flow below the capacity of the motorway. Then that invention might somewhat correct the relative positions of the cars in such a way, that cars are not reaching the weaving point at the same time, but with acceptable gaps in between To-day that process is performed by using a ramp, where the cars on the access and the motorway are travelling several hundred meters in parallal, and the drivers are watching each other optically and controlling their speeds to adapt to the gaps between the cars before weaving
- a traffic management system is fed with traffic information from sensors, S, at various positions along the motorway, on accesses, PI - P3, and possibly at the connected road network N 1.
- the management system might be more or less advanced. It might have functions for continously calculating and predicting of traffic on the given road network. It might have analysis functions for comparison of traffic streams with travellers need for road capacity etc. During rush hours the capacity is many times inadequateat at several links and nodes at the road network, and traffic can be distributed in a way utilizing the road network better and reducing the traffic problems.
- Values on goals for traffic flows can be determined on motorways and access roads. Goals can be determined adapted to various traffic conditions and be given certain values over the day. Those are values, that reduce traffic problems, if they are under control.
- Access roads can be given flow rations, which prevent overloading along the motorway.
- the goal values might be regarded as average guide-lines.
- the traffic is fluctuating and short term variations of the motorway flow might be measured at the nearest upstream S and/or at the exit in Al, and be used by the local access control at P3, for dynamic correction of the onflow in relation to the ration.
- the correction is determined in Cl, P3 or Al and should be based on a prediction of the flow at the access, knowing the upstream measured result.
- the distance LI from upstream S to the access must be long, as the onflow control requires time for actions. That means that there will be a need fo correction of traffic density, gap distances, of the motorway traffic travelling to the weaving zone. Information considering gap distances is given by the information means II .
- Figure 2 is a diagram of the exit control, with the introduction of a "Middle lane", Me.
- Me To the left, upstream in the figure, there are three cars illustrating the intention of changing lanes. The car in the left lane indicates that it will turn to the exit. The first car in the right lane also wants to turn. The other car wants to change to the left lane.
- the small circles at the front and back of the cars illustrate activated blinkers.
- Arrows in the lane show how the cars change lanes and how the cars in the right lane alternatively turn to the exit or continue along the motorway, where Me and the right lane join to continue as the right lane.
- the exit equipment Al has sensors, S, which detect turning information of the cars, and information means I, which inform the cars about their roles including assigning of lanes.
- Al delivers information about the motorway flow, based on how many cars, that turn, and that information is utilized for correcting the goal flow, the ration, at downstream access control.
- the SCA operates from an upstream access (e g the third, (PI), counted from (P3) ) in the following way.
- a traffic signal at the access road is given a first setting, that limits the access flow to the given predetermined value. Measurements and controls are performed based on a relatively short measurement time period (tl), less than a minute. If the access demand is lower than the predetermined value during the time period, the extra flow is given as an additional flow portion to the closest downstream access or the access that needs it more. If the motorway flow instead was larger than the predetermined value, the result might be larger total traffic volume after the access, and the succeeding access and/or accesses further down, are then assigned corresponding decreases of their allowed access flows. In this way the deviations from the goal value are corrected successively along the motorway, and downstream accesses (p2 to P3) are successively given information about what traffic flows can be expected and what corrections to be done from their assigned access flow ratios.
- tl measurement time period
- a measurement of traffic using short measurement periods at exits is anyhow giving opportunities, in second hand decreasing the access flow, not to make packed traffic ahead worse, by further adding of acceess cars.
- a measurement of traffic just before the access connection might be valuable for controlling the final part, the actual weaving process.
- the weaving process is m itself a risky process, especially when one wants to utilize the capacity at maximum.
- the margins then will axiomaticly be correspondingly small.
- Tools facilitating that process imply more safe and more efficient weaving.
- the following theoretical reasoning is a pedagogic example Imagine the motorway and the access consisting of small platforms carrying respective car, and a mechanical system managing the movement of each platform. Then it would be a simple controllable task for a system to successively adapt velocities and gaps of the platforms in such a way, that weaving the platforms from the motorway and the access, would be carried out in a very safe and efficient way
- one way is to identify, for each access car, that motorway car (B), which is to let in the access car (A).
- signal means at suitable intervals along the motorway and possibly the access.
- Those means can be designed in various ways and be positioned in va ⁇ ous ways e g hanging above the road, attached to poles at the roadside etc Here a design is described in more detail as an example
- information signs are put along the motorway. They can be turned on and off and possibly change information. They are screened and directed backwards to the traffic flow. They shall be able to switch on, when the car ahead of (B) is no longer seeing the information, and be on as long as (B) sees it. Successively the next sign is switched on and so on
- the signs can be positioned more or less dense on such a distance, that principally one sign is always on and can be read by (B)
- the car (C) which is following (B), experiences that the signal is not meant for (C), as the sign is turned off when (B) cannot see it any longer, which is at latest when (B) is passing the sign
- Information in a simple design can be a lamp, which is on for (B), when (B) should decrease his velocity, either for increasing the distance to the car ahead or for adapting the arrival time to (A)'s arrival time to the weaving zone
- Car (A) also might get corresponding information, meaning reducing his velocity for avoiding running away from his "gap". It is not always easy for (A) to do a final correction, while driving in parallall with the motorway, and perhaps not even seeing if he might be too far ahead or back.
- infoprmation is easy to apprehend quickly and without misunderstanding.
- the time gaps between cars are small, about 2 seconds, which isn't much time to grasp the information.
- the gap is increased to 3 - 4 seconds to let a car in, the distance will be about 100 m (at 1 10 km/h), which on the other hand is a long distance for seeing detailed information. Therefore it is better there are successive information means ahead, that are successively turned on and create a kind of repeated information to (B).
- Cars equipped with ICC, Intelligent Cruise Control, or distance keeper to the car ahead can obtain information directly to the car equipment, that they are e g (B)-car and what distance to select and also the velocity. That equipment can present and/or automatically bring out the required gap ahead of the car.
- a safety increasing effect is also obtained by lowering the speed.
- the cars had time to run far with 110 km/h.
- Lowering the speed is suitably performed dynamically, when traffic on the motorway is getting dense.
- Lowering levels down to 70 or 50 km/h, is performed in the usual way in steps.
- the position of the access control signal can then be chosen remarkably closer the weaving zone, and the measurement on the motorway and the sign means can also be placed correspondingly closer to the access point.
- the adaption of gaps which now can be shorter, and the weaving process can be performed at a more calm speed.
- the following is suggested for using dynamic velocity adaption.
- the speed on the motorway is high at free flow and less dense traffic e g during most of the day hours.
- the suggested tools are used when suitable. At more dense traffic the velocity is decreased and the given tools being adapted to this situation are used more fully.
- Detecting the car positions can be done from the roadside, possibly combined with the signal means. It can be performed by known types of sensors. One can also use simple sensors, which only detect cars passing and thus trigger the signal means "on and off”. They can also simply measure time gaps between cars and by that survey the adaption of the gap.
- car (B) When car (B) is defined, there are simple methods to survey the process down to the access point. A method is based on prediction when car (B) will reach a certain position . Corrections of predictions can be done successively, dependent on measured deviations from the predicted values. Applying said methods, one can make preparations in time before arriving to the ramp, for allowing an access car (A) to weave in ahead of a motorway car (B).
- Car (A) can also be given a more accurately controlled transport by obtaining a successively updated information about desirable changes to synchronize to the weaving gap.
- cars (A) have relatively large individual differencies in travel times from the ramp- meter signal to the weaving zone It is because the acceleration is carried out by large individual differencies Also the performance of various vehicles e g heavy trucks, play a role.
- the (A)-car is given successive information about its relative position related to the expected gap
- One might e g show two parallall lanes, where the expected gap is marked static on the left lane, and the predicted final position , based on actual velocity status, on the right lane A line from the middle of the gap, across the right lane is marking the target line.
- the symbol of the car (A) might e g shine blue with an arrow up towards the gap line, when the relative position of (A) is predicted to be behind the gap.
- a dynamic management system for (A)-cars would replace the present stereotype ramp-meter system. Often the access cars would be managed up to the motorway individually matched, without any need for stopping at any red signal. A stop might be regarded as one of several steps of different velocities, included in the dynamic speed adaption.
- Another type of preparation for downstream accesses and exits includes the lane changes between the left and the right lanes of the motorway.
- the drivers regularly want to carry out those changes early in time. Weavings between lanes cause an increased accident risk and cause a decreased capacity for the road segment. Simply expressed, the car changing lanes needs reasonable space simultaneously in both lanes just while changing.
- an effective dense traffic in the left lane is necessary, for allowing a maximum number of cars from the following access road, and offering the cars space enough for weaving into the motorway
- Special weaving zones might be designed at the mentioned road segments There is one segment in the position between an exit and the following access, where it is advantageous to weave from the right to the left There the exit has caused gaps, related to the cars that turned off. Then there are gaps in the left lane open for weavings from the right, while the right lane isn't completely filled up.
- the extra capacity can be used for weaving to the left, increasing the possibility for added flow from the following access
- Contmous marked lines force the cars to stay in their respective lane as a start. Then leaving cars, (A)-cars, are allowed to change from left to int. lane. Before the shift such a car should indicate the shift by the right blinker.
- the car behind in the right lane, (B)-car might indicate a shift to int. lane with his blinker and weave into int. lane after (A). Also the car after (B) can be given possibility to select int. lane, if he e g wants to weave further on to the left lane.
- the closest car, staying in the right lane, (C) has to watch for and keep the safe distance to his related car ahead, which now is in the int. lane.
- the (C)-car watches the safety distance to the car ahead in the int. lane.
- the rule utilized both here at an exit and at an access is that the first weaving car (A), is supplying a signal (blinker).
- the car behind in the neighbouring lane, car (B), is responding with a signal and is turning after (A).
- the other cars keep their o ⁇ ginal safe distances, also if the car ahead now is in another lane, until the weaving process is ready. Local access control.
- the access control system can help defining (A) and (B). Upstream the weaving zone, at the "isolated" part between the ramp and the motorway lane, where it is a line separation, it is shown for (A) and (B), possibly with a common sign, the own position related to the other's.
- (A) might be presented an arrow symbol, indicating where the gap and the (B)-car is positioned relative the own position, and by that identifying the actual gap and (B)-car.
- (A) might take action to get the position (on the ramp) definitely ahead of that car, being a (B)-car, and after that giving signal with blinker, showing the desire to weave into that gap.
- the car behind replies with his opposite blinker (the right one at right driving), accepting the role as (B)-car.
- the ramp should with this method implemented, possibly be adapted by a design of two weaving zones. First an early one on the ramp, where (B) is weaving, then one more at the end of the ramp, where (A) and (B) are weaving. Further more weaving from the inner motorway lane to the outer lane (right) should be forbidden during the local and possibly the preparatory access control process. As a further safety action, the ramp might be designed with a returning road lane for those drivers on the ramp, which anyhow could't find their safe gap for weaving. Without the above presented methods and tools, i e as it is to-day, the returning road should be of still more help.
- exit and access of a motorway are connected as a couple to other traffic links, with the exit generally upstream.
- the distance between the exit and the access might be relatively short, and there are advantages in utilizing the exit control also as as a preparatory access control.
- the following example is illustrating how that can be performed.
- the exit is modified, utilizing the beginning of what later becomes the exit, as a third lane.
- the cars in the right lane will experience a lane division, where the system can distribute cars between the lanes.
- Cars in the left lane at this exit wanting to leave at the exit signal as an (A)-car and shift to the int. lane, when (B)-cars or the system has prepared space in the int. lane.
- Cars in the int. lane, arriving from the right lane are now given prepared space in the left lane. This is done by identifying certain cars as (B)-cars, i e such cars that should let in cars ahead.
- the right lane is divided into one link that continue as the ordinary exit, and another link that is combined with the int. lane, as a continuation of the ordinary right lane.
- those cars are prioritized, that originally are in the left lane and are going to leave at the exit. For support in the weaving process, they ought to give signal early in time.
- the system can detect the signal and give support by managing the choice of the right lane cars for the int. or the right lane. Added to that there is the need for utilizing the left lane, to be able to achieve a maximum of space in the right lane, for the cars arriving at the next access.
- an internal surveillance control function When parts of or the whole system is implemented, there should be included an internal surveillance control function. Its task is registering from measurements the real result of the actions, for a successive updating of functions and algorithms, by which the system is adapting and improving. That can partly be done automatically built in the control process, and partly by the means of failure reports, alarms, statistical result reports etc.
- the measuring stations, that are directly motivated by the purpose of control should be useful also for the surveillance function.
- complementary measuring stations e g after the ramp, which are delivering traffic status, showing the result of the access control, i e the effectivity and safety of the traffic out from the access process, and the traffic meeting the downstream strains.
- the system can be looked upon including four levels of actions as described on the first page, and one interesting example is the following:
- Methods and means are implemented along a motorway in direction towards a city with principally increasing traffic closer to the city during the morning rush hour, where the system principally is using only level One for control of an upstream access, where the total traffic is relatively small, and the system is using principally combinations of level One and level Three for a downstream access, where the traffic is small and the requirements are large for a well flowing traffic, and when high effectivity is needed, the system can be complemented with level Two upstream this access, and in certain cases, the system can be equipped for the access with principally a combination of level One and level Four, and alternatively the system for the motorway can be introduced in various ways e g by using mainly only level Four or One on one or several accesses, and the system can also, when needed, be equipped for an access with all levels, applied to an applicable extent.
- Means and methods concerning level One where the motorway and the access flows are controlled in relation to targets and rations for short and longer time periods, and for short time periods a corresponding packet of cars can be predicted to reach downstream accesses at earlier or later time stamps, and for those accesses, the allocation of access traffic can be corrected considering the upstream observed deviation, e g if there is observed a larger or smaller volume of cars travelling, the next following access, or if the need for compensation is larger for another access, that access is allocated a compensating ration, the traffic being successively readjusted along the motorway for those deviations, that anyhow can arise in spite of the control, especially seen over short time periods, and seen over longer time periods, two or more short ones, the respective access is obtaining compensating allocations, dependent on allocation deviations from earlier periods compared with the valid targets and rations, and the valid target and ration can successively be updated, alternatively automatically by the traffic management system, which is supplying input data based on the topical needs at the road network.
- Means and methods, where the system contributes in effectively packing the traffic in Le lane, by estimating short term traffic density from measurements, and from the result appoint (B)- cars in Le, which are given the task to take out gaps ahead, and that process can be prepared already before the weaving zone, and cars in Ri experiencing gaps for them in Le, can take on the role as (A)-cars, e g showing that with blinker, and if there is an Int lane, select that lane for further weaving together with (B) to Le lane, and if there isn't an Int lane they can directly weave into Le in the gap ahead of (B), and the system can be expanded with one or more added functions; as giving information for identifying also (A)-cars, and as giving information to (B) about taking out a suitable gap in front of (B), and as using knowledge about this process for prediction of downstream traffic for control of the following access.
- Means and methods concerning level Three where the system helps (B)-cars in taking out gaps, and makes adjustment of the related (A)-car control, by e g correction of the ramp signal status, or alternatively timely control of (A) for arrival to the weaving zone, or both in combination, or alternatively by timely control of (B) or (B) and (A) to synchronize the arrival to the weaving zone, and the system can be expanded with one or more added functions; as giving information also to cars behind (B) to handle the consequencies of (B)'s actions e g braking, and as providing speed adjustment with dynamic signs before the weaving zone, dependent on matters as traffic density or accident risk, and lane separation lines can be added for weaving control between the motorway lanes, e g not allowing weaving from Le to Ri next to and at the ramp.
- the ramp is designed with two weaving zones, the first one concerns weaving of (B)-car to the ramp and the second one concerns weaving of (A) and (B) to Ri lane, alternatively designing the ramp with a return road for access cars or both those alternatives in combination.
- speed limitation is an added function in the system for selectable use on the levels Two, Three and Four
- the speed message can be static, e g valid for some time periods or dynamically changable, depending on time of day and/or traffic situation, the velocity being an essential parameter in the access control
- the speed information is given by the system in a certain design, as a part of an integrated information, and in another specific design the speed information is given indirectly, e g by symbols showing a car position relative a selected compared position e g the position of another car.
- Means and methods where the system is equipped with system and function control, including estimating the real result of what traffic might look like from measurements, and compare that with the target for the system processes, wherein there are included the use of rules, predictions and management, successively updating functions and algorithms, and/or detection of deviations, which indicate or are estimated to give rise to dangerous situations and possibly risks for drivers to break rules.
- Means where the design of the information presentation means, are given by the following alternative basic concepts; the means including simple symbol signs as lamps, turning on and off, prisms turning, etc, where the rule simply is that the car (driver) obtaining signal saying "(B)-car” is appointed (B)-car and shall fulfil his stipulated task; i e principally take out gap to the car ahead, offering (A)-car to weave into this gap, the (A)-car e g an access car, alternatively the means including more detailed information, using illustrating symbols, as e g arrows modelling a car from the right turning into the gap in front of the appointed car, alternatively with a more detailed information marking the gap in front of (B), and alternatively relating the gap to the actual gap or using symbols for increase or decrease of the gap size, and alternatively using symbols for limiting or decreasing the velocity, with the objective of changing the gap and/or the arrival time at the weaving zone.
- Means where the system controls the arrival time of the (A)-car at the weaving zone by using functions, where one alternative consists of a speed control of (A), including the speed value zero, and successively manage (A) from the start of the acceleration road segment to the weaving zone by information means, in an alternative embodiment the means includes a light source with a lobe successively swept in front of (A) at a smoothly increased speed, which (A) can follow in about the same way as following a car, or alternatively using marks at the road side, which successively are activated at the pace (A) should follow, or alternatively using speed signs with successively increasing speed, alternatively dynamically adjustable for correcting the position of (A) relative to the planned, or alternatively an embodiment, which will show if (A) is before or after the allocated travel plan by using alternative presentation designs e g a sign with lamps in a row and with different colours, where the intermediate lamp is showing that the car is according to plan, the low lamp that the car is below and needs to increase, and the upper lamp that the car is
- the information means are designed including a light source e g a lamp lightening a selected part of the road surface in front of (B)-car or (A)-car, and the light source can be designed to have one or more radiation variables, as several colours, several lobes, controllable lobes, whereby a corresponding simple or integrated message can be transferred, and the system can be expanded including various surface conditions of the road, which transform or reflect the radiation from the radiator according to its characteristics, and the surface can be given different patterns or symbols, further increasing the the possibility for transfer of information to the car drivers, e g a symbol meaning increase of the gap, can be shown successively on the road surface in the driver's view e g within the same view covering the car ahead.
- a light source e g a lamp lightening a selected part of the road surface in front of (B)-car or (A)-car
- the light source can be designed to have one or more radiation variables, as several colours, several lobes, controllable lobe
- car equipment is used for transfer of information from the system to the driver, and the communication can be performed using various types of media, e g radio, light or infrared technology, and communication can be organized by road side, locally bounded links, or more area covering means e g cellular types of radio, and here the information is corresponding to the earlier described and is presented according to the rules for presentations in a car, which also creates possibilities to present information by sounds, avoiding disturbance of the driver's eyesight control of the traffic situation, and more information can be transferred to the car equipment, information in its turn processed by the car equipment for actions and for suitable presentation, e g related to other information for the driver.
- media e g radio, light or infrared technology
- communication can be organized by road side, locally bounded links, or more area covering means e g cellular types of radio, and here the information is corresponding to the earlier described and is presented according to the rules for presentations in a car, which also creates possibilities to present information by sounds, avoiding disturbance of the driver's eyes
- the car is equipped with distance controlling equipment, which can be fed with information about distances and contribute in taking out gaps, e g the gap for the (B)-car, and the system can be expanded also for using the speed control of the cars, e g for control of the travel plan of the car, where e g already at the start of the access segment, the (A)-car obtains information for the whole travel process, and also along the road, the car can have one or more points of control for possible adjustments of the continous travel, and further information can be transferred to the car equipment for further processing by the equipment.
Abstract
Description
Claims
Priority Applications (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP10510153A JP2000516366A (en) | 1996-08-09 | 1997-08-07 | Method and apparatus for controlling a highway |
DE69711194T DE69711194T2 (en) | 1996-08-09 | 1997-08-07 | METHOD AND EQUIPMENT FOR MOTORWAY TRAFFIC CONTROL |
EP97934845A EP0920689B1 (en) | 1996-08-09 | 1997-08-07 | Method and equipment for motorway control |
US09/242,027 US6320515B1 (en) | 1996-08-09 | 1997-08-07 | Method and equipment for motorway control |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
SE9602950A SE509762C2 (en) | 1996-08-09 | 1996-08-09 | Method and device for highway control |
SE9602950-9 | 1996-08-09 |
Publications (1)
Publication Number | Publication Date |
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WO1998008207A1 true WO1998008207A1 (en) | 1998-02-26 |
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PCT/SE1997/001331 WO1998008207A1 (en) | 1996-08-09 | 1997-08-07 | Method and equipment for motorway control |
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US (1) | US6320515B1 (en) |
EP (1) | EP0920689B1 (en) |
JP (1) | JP2000516366A (en) |
DE (1) | DE69711194T2 (en) |
SE (1) | SE509762C2 (en) |
WO (1) | WO1998008207A1 (en) |
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EP1202233A1 (en) * | 2000-10-31 | 2002-05-02 | Arcadis Bouw/Infra B.V. | Traffic control system |
NL1016511C2 (en) * | 2000-10-31 | 2002-05-02 | Arcadis Bouw Infra B V | Traffic management system. |
DE10101652B4 (en) * | 2001-01-16 | 2008-05-15 | Daimler Ag | Method for traffic-noise reducing influencing the driving behavior of vehicles |
NL1036041C2 (en) * | 2008-10-09 | 2009-11-03 | Roy Farley Gene Van Sprang | Drive system for road, uses mandatory speed, extensive vehicle detection, and navigation together to ensure balance between traffic and road capacity |
CN111882878A (en) * | 2020-09-02 | 2020-11-03 | 烟台大学 | Method for maximizing traffic capacity of key roads based on traffic flow prediction |
CN111882878B (en) * | 2020-09-02 | 2021-07-02 | 烟台大学 | Method for maximizing traffic capacity of key roads based on traffic flow prediction |
Also Published As
Publication number | Publication date |
---|---|
DE69711194D1 (en) | 2002-04-25 |
SE509762C2 (en) | 1999-03-08 |
SE9602950D0 (en) | 1996-08-09 |
SE9602950L (en) | 1998-02-10 |
JP2000516366A (en) | 2000-12-05 |
DE69711194T2 (en) | 2002-11-14 |
EP0920689A1 (en) | 1999-06-09 |
EP0920689B1 (en) | 2002-03-20 |
US6320515B1 (en) | 2001-11-20 |
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