DE19823135A1 - Traffic data acquisition for respective control of light signal system - Google Patents

Abstract

The method involves using frequency-modulated radar for acquiring traffic data for a corresponding control of light signals, whereby frequency-modulated radar waves (6) are emitted against a drive direction of vehicles (1, 2) to be detected, and reflected waves of objects located in the radar radiation beam are received, and are analyzed with respect to run-time and frequency spectrum. A classification of the vehicles is preferably performed through temporal analysis of the frequency spectrum at passage of the vehicles through the radiation beam. An Independent claim is provided for a corresponding data acquisition arrangement.

Description

The invention relates to a method for Traffic data acquisition for traffic-dependent control of traffic signal systems and an arrangement for implementation this procedure.

In order for the traffic-dependent control of Traffic signal systems the necessary traffic data, such as Presence of a vehicle in front of the stop line Request the green phase, time interval between moving vehicles (net time gap) for Time gap control, that is, for example, termination of the green wave when a threshold value for the Time gap, determining the speed of the vehicles as well as classification of vehicles - that is, Differentiation between cars, trucks, vans, each with and without a trailer, motorcycle, bicycle - to determine A large number of detectors have been used to date.  

This is, for example Induction loop detectors, which are capable in themselves are to determine all the parameters described. As The disadvantage here is the introduction of Induction loop in the street and the associated Possibility of wear due to mechanical stress.

Infrared detectors are also known for this purpose while recognizing stationary and moving vehicles, one Classification and a speed determination however not allow.

Ultrasonic detectors have also been used but which only the parameters with minor errors vertical installation can determine.

Finally, Doppler radar devices are used (Traffic radar) whose transmitters are continuous emits electromagnetic waves, but their detectors based on measuring the frequency shift (Doppler effect) of moving vehicles unable are to detect stationary vehicles.

The present invention is therefore based on the object a process and avoiding the disadvantages mentioned an arrangement for reliable and comprehensive detection, the for the traffic-dependent control of Traffic signal systems to indicate necessary traffic quantities.

This object is achieved in that frequency modulated radar is applied.

This has the advantage that all for the control of Traffic lights need traffic data on simple Way can be won.  

It is particularly advantageous if frequency-modulated Radar waves against the direction of travel of those to be detected Vehicles are sent out and that of in the Objects located on the radar beam received reflected waves and in terms of transit time and Frequency spectrum to be analyzed.

Another advantageous embodiment of the invention in the fact that a classification of vehicles by temporal analysis of the frequency spectrum when driving through the Vehicles is carried through the beam of radiation. A advantageous development of the invention provides that the Radar waves are pulsed and that the frequency during the Pulse is variable.

A particularly advantageous arrangement for Traffic data acquisition for traffic-dependent control of traffic light systems is that a transmitter for frequency-modulated radar waves is provided that the Output of the transmitter via a send-receive switch with the Is connected to a radar receiver with its antenna Input via the send-receive switch with the antenna is connected that the output of the radar receiver to a Fast Fourier transform device is connected and that an output of the device for fast Fourier transform with the input of a Classifier is connected.

In an advantageous embodiment it is provided that which with their beam direction against the direction of travel to be detected vehicles aligned antenna above the Traffic light system is attached.

An embodiment of the invention is in the drawing represented with several figures and in the following Description explained in more detail. It shows:  

Fig. 1 a possible traffic scenario,

Fig. 2 is a block diagram of a radar system and

Fig. 3 shows some curves of signals occurring in Fig. 2.

Fig. 1 shows a possible road traffic conditions, in which two cars 1 and 2 are shown in front of a light signal system 3. A radar device 4 is installed via the traffic light system 3 . This device 4 can be provided, for example, on a nearby light pole or on a house wall in an area above the light signal system 3 .

The radar device 4 transmits a pulsed frequency-modulated radar wave 6 against the direction of travel of the vehicles 1 and 2 , via which it is reflected, among other things, via an antenna 5 . As is known, the position or distance of the vehicles can now be determined from the transit time, that is to say from the time difference between the transmission of the signals and the reception of the echoes, it being possible for several vehicles to be identified individually in the same direction. Both the so-called gross time gap BZL and the so-called net time gap NZL of the vehicles 1 and 2 located behind one another can be determined, which move at a speed of v1 or v2 in the direction of the traffic light system 3 . Furthermore, the size of the reflecting object can be inferred from the characteristic of the frequency spectrum of the frequency-modulated signal. A vehicle can then be distinguished from a bird or a manhole cover, for example.

FIG. 2 shows a block diagram of a radar system which essentially consists of a transmitter 11 , a receiver 12 and the antenna 5 . The transmitter 11 in this case comprises a generator 13 for generating the modulation signal, a high-frequency generator 14 for generating the carrier wave which is modulated by the signal of the generator 13 , a subsequent amplifier 15 for amplifying the carried signal and the 16 connected via a transceiver Antenna 5 for transmitting the radar wave 6 .

The reflected waves or echoes picked up by the same antenna 5 are fed via the switch 16 to the receiver 12 , which is blocked during the transmission time (pulse duration). The receiver 12 here consists of an input amplifier 17 , a demodulator 18 , a device 19 for fast Fourier transformation (FFT) and a classifier 20 , at the output 21 of which a control signal for a light signal system control unit can be removed.

In the case of a radar measurement, the signal a ( FIG. 3) generated by the generator 13 is received again as an echo signal b ( FIG. 3) after being transmitted and transmitted via the antenna 5 after reflection from obstacles and in the receiver 12 after corresponding demodulation Fourier-transformed in demodulator 18 at 19 . The resulting frequency spectrum c is fed to a classifier 20 . There, individual properties of the frequency spectrum c are divided into classes, for example by comparison with data stored in a table. This allows a distinction to be made between vehicles d and other things or objects, such as birds e, manhole covers g, etc. In addition, it can be determined what type of vehicle it is, for example, not only a distinction can be made between a car and a truck, but also between a car and a motorcycle or bicycle. The classifier 20 then outputs a corresponding control signal intended for the traffic signal control unit at its output 21 .

In addition, the transit time t _D between the signal a (for example at the time t _s ) and the echo b (at the time t _m ) and thus the distance of the objects can be determined by the frequency position of the received signal, for example the spectrum e.

Claims (6)

1. Process for data acquisition for the traffic-dependent control of traffic signal systems, characterized by the use of frequency-modulated radar. 2. The method according to claim 1, characterized in that frequency-modulated radar waves ( 6 ) are emitted counter to the direction of travel of the vehicles to be detected ( 1 , 2 ) and that the waves reflected by objects in the radar beam beam are received and analyzed with regard to transit time and frequency spectrum will. 3. The method according to claim 2, characterized in that also a classification of the vehicles by time Analysis of the frequency spectrum (c) when driving through the Vehicles is carried through the beam of radiation. 4. The method according to claim 2, characterized in that the radar waves are pulsed and that the frequency during the pulse is variable.   5. Arrangement for traffic data acquisition for the traffic-dependent control of light signal systems, characterized in that a transmitter ( 11 ) for frequency-modulated radar waves is provided that the output of the transmitter ( 11 ) via a transceiver switch ( 16 ) with the antenna ( 5 ) is connected that a radar receiver ( 12 ) with its input via the transceiver switch ( 16 ) is connected to the antenna ( 5 ), that the output ( 21 ) of the radar receiver ( 12 ) to a device ( 19 ) for fast Fourier transformation is connected and that an output of the device ( 19 ) for fast Fourier transformation is connected to the input of a classifier ( 20 ). 6. Arrangement according to claim 5, characterized in that with its beam direction against the direction of travel of the vehicles to be detected ( 1 , 2 ) aligned antenna ( 5 ) above the light signal system ( 3 ) is attached.