EP2075775A1 - Method for documenting near simultaneous traffic violations - Google Patents

Abstract

According to the invention, a first measurement data packet M ₁ , a first measurement time t _M1 and a first image data packet B _{1 are} formed by a first vehicle 1 and measurement data packets M _{X are} formed by further vehicles _X at further measurement times t _MX , to which duplicates of the first image data packet B _{1 are} assigned if the further measurement times t _{MX are} within a predetermined time range a after the first measurement time t _M1 .

Description

The invention relates to a method for detecting and documenting traffic violations, such as red light violations or speed violations.

From the prior art, a variety of methods for detecting traffic violations are known in which the detection of a specific event, a camera is triggered to capture image data from the infringer vehicle.

Such events can z. Example, the detection of an excessive speed of a vehicle or the falling below a predetermined distance of the vehicle to a reference point, entering a traffic-controlled penalty area or detecting predetermined characteristics of a vehicle, such as exceeding a minimum length, be.

Depending on the event, the camera can be triggered at least a second time, usually after a predetermined time, in order to obtain at least two image data sets from the infringing vehicle.

For a method according to the invention it is immaterial, whereby the camera is triggered. To simplify, all possibilities for this purpose are summarized as triggering, caused by an infringing vehicle.

In terms of application, the methods for detecting traffic violations and suitable devices differ from those in which the measuring range of a measuring device and the object field of a camera are limited to only one lane and those in which the measuring range and the object field cover a plurality of lanes ,

By means of a measuring device, which may be located on or in the roadway sensors, Radarmessgeräte, laser measuring devices or video cameras with image processing systems, which are the measuring range or the measuring ranges driving vehicles appropriately. The respective vehicle data of interest is determined from the measurement results.
This is usually the vehicle speed, a detection signal and / or the distance to the measuring device. For measuring devices whose measuring range extends over several lanes, the vehicle data of interest could also include the angle to the receiving axis of the measuring device in order to distinguish vehicles that are simultaneously in the measuring range or in the measuring ranges and driving on different lanes.

From the measurement results of several individual measurements, each of which provides a measurement data set, further specific vehicle data can be derived, such as the track course of the vehicle through the measuring range or the vehicle length. The vehicle-specific data formed from the measurement results of a plurality of individual measurements are stored together with identification data such as date, time, location and device identifier each as a measurement data packet, that is, all stored to a vehicle measurement data sets together form a measurement data package.

The image data sets obtained by the camera are also stored, with each image data set to be assigned to a vehicle forming an image data packet.

According to the prior art, the measurement data packet and the image data packet are stored in association with one another. The unambiguous assignment is possible because the measurement of a vehicle and its recording are linked actions that begin in a known temporal correlation with each other.

To detect a speed violation, z. For example, at the moment the meter verifies the overspeed, a first shot is fired or the photograph is triggered when the vehicle is at a predetermined distance from the camera, which is determined by the speed and a delay time. In both cases, the triggering of the camera is initiated by a signal from the measuring device during the measuring process, whereby an association of the measurement and image data packets to each other is unique.

Similarly, there are methods in which the camera is triggered by a signal independent of the meter, z. B. from an induction loop. In this case, the unique assignment of the measured data packet to the associated image data packet takes place via the fixed temporal relationship of the data acquisition. Thus, if the detection of the measurement data and the image data begins when the vehicle traverses the induction loop, then the measurement data packet and the image data packet are assigned the same time over which the measurement data packet and the image data packet can be unambiguously assigned to one another.

The link between the measurement data packets and the image data packets, regardless of how it is realized, is always realized according to the prior art by a one-to-one association based on a known temporal correlation between the data packets. A fixed temporal correlation is given when a first measurement time and a first recording time coincide in time or have a defined time interval to each other.
Although the temporal correlation is not fixed, it is known when a delay time is derived from the measured speed and the known or measured distance in order then to trigger the photograph at a predetermined distance from the vehicle to the camera.

One-to-one means that exactly one image data packet is assigned to each measurement data packet and exactly one measurement data packet is assigned to each image data packet.

When a measurement data packet and an image data packet are assigned to each other is irrelevant, d. H. they can also be merged immediately after the data acquisition and stored together as a vehicle data package.

This type of data processing has proven to be disadvantageous for solutions in which several vehicles can be adequate at the same time or almost simultaneously.

After the camera is triggered by a first vehicle, the camera is not ready for a certain period of time to be triggered by a second vehicle become. How long this period is depends in particular on how many follow-up shots are taken each time after a first take.

In the case of an alleged red light infringement, after a first shot which the vehicle detects on the retaining strip, a second one, which shows the vehicle at the traffic light or in the crossing area, and possibly a third shot, usually follows. These further shots are taken either after a fixed time interval or depending on the speed of the infringer vehicle at a time when the violator vehicle is expected to be at a certain location.

For vehicles that are appropriate in this resulting dead period and identified as injured vehicles via the measurement results, there are no recordings, so no image data package. It is not possible to create a vehicle data package for these infringing vehicles, which means that these traffic violations can not be documented and therefore not punished.

A trivial solution to this problem would be to install one camera per lane, which will be activated each time a violation attributable to that lane is detected. However, this leads to higher acquisition, installation and maintenance costs for the operator.

The invention is based on the object to provide a method with which almost simultaneously metrologically detected traffic violations can be documented with only one camera.

This object is achieved by a method having the features of claim 1.
Advantageous developments are described in the subclaims.

Fig. 1

ein Flussdiagramm für den Verfahrensablauf

The method is explained in more detail below by way of example with reference to the drawing. It shows:

Fig. 1

a flow chart for the procedure

The invention is based on the idea of assigning an image data packet B ₁ , which is assigned to the measurement data packet M, of a first infringing vehicle 1, to the measurement data packets M _{X of} further infringing vehicles X which could trigger the camera within a predetermined time interval a after the first violator vehicle 1.

A camera capturing an object field extending over several lanes captures all vehicles that are in the object field at the time of triggering. These are in particular vehicles that drive at the same height or just behind the violator vehicle triggering the camera on other lanes.
The time interval a is set accordingly so that all vehicles that are detected within a, are displayed on a recording.
How long this time interval can be depends essentially on the position and size of the object field and the speed of the other infringing vehicles.
Such a time interval will generally be less than 10 s and will be less than 2 s.

All traffic violations that are detected within such a time interval a should be understood as almost simultaneous.

Equally known from the prior art methods for detecting traffic violations, a meter, z. B. a radar device and a camera arranged to a roadway, so that the measuring range of the measuring device and the object field of the camera overlapping overlap several lanes of the road.

Vehicles that pass through the measuring range monitored by a measuring radiation will be suitable on several occasions on their way through the measuring range. Vehicle-relevant data such as speed, distance and angle are formed from the measured values per time unit and assigned to the measurement time as a measurement data record stored. All measured data sets, caused by the same vehicle, are combined and stored as a measurement data package.

In addition, the vehicle is also photographically recorded. The camera is triggered in the broadest sense by the vehicle itself, regardless of whether the signal to trigger by the meter or z. B. is generated by an induction loop. A first image is taken of the object field, showing the camera triggering the camera. Further follow-up shots can be made. An image data set is created per image, a plurality of image data records form an image data packet and are stored at a recording time, usually assigned to the recording time of the first image.

The measured data packets and the image data packets are stored identifiable over the respective first measuring time or the first recording time.

In contrast to the prior art, where the image data packets and the measurement data packets are uniquely assigned to one another, an unambiguous assignment of the measurement data packets to an image data packet takes place according to the invention, based on a predetermined temporal correlation range.

That is, each measurement data packet is assigned exactly one image data packet, but each image data packet can be assigned multiple measurement data packets.

The method is described below with reference to a flow chart based on Fig. 1 explained.
In the state of the art, a measurement data packet M ₁ , determined by a first measurement time t _M1 , is detected by a first violation vehicle 1 via a known temporal correlation and an image data packet B ₁ determined by a first acquisition time t _B1 and caused by this first violation vehicle 1 assigned to form a vehicle data packet F ₁ .

Subsequently, it is checked whether there are further measurement data packets MX (X> 1) whose further measurement times t _MX within a time interval a after the first Measuring time t _M1 lie. If this is the case, the image data packet B _{1 is} duplicated and the duplicate of the image data packet B _{1 is} assigned to the respective further w measurement data packet M _{X in} order to form further vehicle data packets F _X.
If this is not the case, it is checked whether the camera is ready and if necessary, the procedure starts again. The vehicle data packets F _{1 formed} and possibly F _X (X> 1) are stored in memory in memory locations j.

If multiple recordings made by the infringer vehicle, the time interval a may be chosen to be at most so large that the second infringing vehicle is also found in all image data sets of the associated image data packet.

It is advantageous to set the time interval a as a function of the speed of the infringing vehicles. The smaller the speed difference between the first and second infringing vehicle, the greater the time interval a can be selected. The greater the difference in speed, the more likely it is that the second vehicle will not be detected on all recordings.

The time interval a can also be a fixed quantity in a simplified manner. In particular, if only one shot is triggered, or if one can expect almost equal speeds of the infringing vehicles.

If only one shot is fired, the time interval may be chosen to be sufficiently large to merely assure that the vehicle was already in the object field of the camera when the shot caused by a preceding infringer vehicle was fired.
In practice, a time interval a of less than 10 s has proven to be a suitable time interval. Advantageously, the time interval a is set equal to the dead time of the camera, that is to say the time interval between a first triggering caused by an infringing vehicle and the point in time when the camera is ready to be triggered by another infringing vehicle.

Claims (10)

Method for documenting almost simultaneous traffic violations, in which measurement data are acquired by a first vehicle 1 traveling through a measuring range predetermined on a lane with several lanes and stored as measurement data packet M together with a measurement time t _M1 and by the first vehicle a camera is generated at a recording time t _B1 a recording which is stored as image data packet B ₁ and between the recording time t _B1 and the measurement time t _M1 a known temporal correlation exists, which allows the image data packet B ₁ uniquely the measurement data packet M, assign to form a first vehicle data packet F,
characterized,
that for further vehicles X, which drive through a predetermined measuring range, measurement data are recorded and stored as measurement data packets M _X together with measurement times t _MX and are checked to see whether their measurement times t _{MX are} within a time interval a after the measurement time t _M1 and optionally the image data packet B _{1 is} duplicated in order to allocate it to the respective measurement data packets M _{X in} order to form further vehicle data packets F _X. Method according to claim 1, characterized in that
that a measuring range is specified for each lane. Method according to claim 2, characterized in that
that the measuring ranges are determined by sensors located in the roadway. Method according to claim 3, characterized
that the vehicle speeds are recorded as measured data. Method according to claim 1, characterized in that
that only one measuring range is predetermined by a measuring radiation covering several lanes. Method according to claim 5, characterized in that
that the measuring radiation is a radar beam. Method according to Claim 6, characterized
that the measured data are the speeds of the vehicles, their distance from a measuring device and their angle to an axis of the measuring device. Method according to one of the preceding claims, characterized
that the time interval a of less than 10 s, in particular less than 2 s. Method according to claim 8, characterized in that
that the time interval a is determined as a function of the speed difference between the vehicles. Method according to claim 8, characterized in that
that the time interval a is given and represents a fixed size.

Images