DE2318259B2 - Method and device for controlling a traffic control system - Google Patents

Description

The invention relates to a method of control

a traffic control system with a plurality of signaling devices and a device for implementing this method.

From the German Auslegeschnfl HW.XS.iy _un j also from the Swiss patent specification 434 035

are already methods and devices for controlling traffic, especially motorized traffic Traffic known by means of remotely controllable signaling devices. These are remotely controllable signaling devices from a control center via a

Control channel, for example a control line, supplied with certain commands that ? .. B. cause a number indicating a recommended speed to light up or ensure the signaling of a certain direction of travel to be observed.

Due to the fact that in the implementation of the known method with a central specification the special control commands of each individual signaling device a variety of information / u are transmitted to the individual signaling devices

must arise both in terms of the required Transmission channels or control lines as well as with regard to a sufficiently fast transmission with all this information, considerable difficulty.

A traffic control system of the type mentioned above is used, for example, to signal an optimal one Route to a parking facility currently still free, such as B. a Parking garage or a parking area is required. Although more and more parking facilities in urban regions, how parking areas and especially multi-storey car parks are created arise for those in such Motorists circulating in the region repeatedly encountered significant difficulties when it came to this It is about finding a suitable parking option in the least possible time. It is already common, for example at the entrances in a parking garage or in a neighboring street to put up a sign that indicates, oh my

There are still free parking spaces available or whether the parking garage is already occupied. Such advertisements are but only recognizable in the immediate vicinity of the car park in question. They are also of no use if

the car park is already occupied, because then the car driver who hits the car must open another car park, which, firstly, he does not even know whether there are still vacancies and, secondly, whether it is being taken into account the current traffic situation can also be reached within a useful time. Would be more useful Information about the current parking possibility in the closer and further surroundings Jes relevant parking garage b / w. a certain Region, preferably taking into account both the current occupancy status neighboring parking garages, as well as possibly the current traffic situation. The motorists looking for a parking space would be then informed about the actual situation at an early stage. You could then be aware of the actual Situation or by observing the appropriate signaling equipment, your choice of the one to be visited Meet the parking facility appropriately.

On the one hand, there is thus a need to display the occupancy status of parking facilities in a wider radius, on the other hand for the display of a for the achievement of such Parking system, taking into account the current traffic situation, the most advantageous route. In extremely dense traffic or standing columns of vehicles, it can be advantageous prove to go to a parking garage a little further away, for which the access conditions are currently available are cheaper.

While in the example mentioned the destination is a parking facility, there are also others Cases in which a control of signal devices with regard to an optimal route to be a certain goal would be desirable, e.g. at sporting events or other large events. Also in the case of an existing or impending traffic collapse or with the Such controllable signaling devices would be such a controllable signaling device advantageous.

The object of the invention is to provide a method for controlling a traffic control system with a plurality of signaling devices in which only a minimum of information on the individual signaling devices must be transmitted and still a large number of such signal devices reliably and can be controlled according to the respective requirements. The device for Implementation of this method should be through circuit simplicity, operational reliability as well characterized in that they gave way in particular without the use of additional signal lines / one Central and the individual signaling devices can be realized.

That is the solution to the task according to the invention Enabling method according to the invention is characterized in that the location of each signal device at least two parameters that are the same for all signaling devices are transmitted by signals and that at the location of the signaling device from the parameters received and from location-related, information stored in the signaling device Control signals for the external organs of the signaling device are formed.

Turning away from a central control of the individual signaling devices, according to the above Rather, measures on the spot, d. H.

an evaluation of parameters is carried out at the signal device itself, and an evaluation then takes place Control depending on transferred parameters and local conditions, which are in the Central in no way be taken into account. This has the advantage that only a minimum of information must be transmitted and accordingly the information transmission possibly even over Existing lines, e.g. B. power lines, can be done with sufficient speed.

A preferred embodiment for carrying out the method according to the invention is distinguished from a controllable signaling device that has a receiving device for at least two parameters transmitting signals is assigned, as well as an expansion device connected downstream of the receiving device for generating criteria for the automatic control of display elements of the signaling device.

Further advantageous refinements of the invention emerge from the subclaims.

In the following the invention is explained by way of example with reference to the drawing. It shows
Fig. 1 is a block diagram of a first embodiment

^a 5 example,

2 shows an example of a pulse telegram,
3 shows the course of a pulse train in the ideal case. F i g. 4 a series of diagrams,
Fig. 5 is a circuit diagram of a clock,

6 shows a coding table.

Corresponding parts are identified identically in all figures.

1 shows a block diagram of a first exemplary embodiment. According to this first embodiment

For example, the parameters to be taken into account by a signaling device 1 are given by a Power network 2 superimposed signals, in particular tone-retentive pulse sequences, supplied. Different such methods are suitable for the present purpose. For the superposition of such pulse trains ouch! a power network and for receiving it are already different methods and devices known.

For the underlying of the present invention Remote control receivers whose selection means are N-path filters are also particularly suitable for this task exhibit.

To transmit the signals containing the parameters mentioned, an ion-frequency pulse telegram is superimposed on the high-voltage network 2 by a remote control transmitter. In the present exemplary embodiment, which is intentionally kept simple in the interest of easy comprehensibility, such a pulse telegram has a start pulse. which are followed by four intervals in which the remote control transmitter marks a pulse or a pulse gap. In addition to the start pulse S , the pulse telegram in the present example contains four information bits. FIG. 2 shows an example of such a pulse telegram which, including the stop pulse, displays the bit sequence 10101. What possibilities such a pulse telegram includes with regard to the transmission of information and how it can be evaluated is explained in the further course of the description.

A sound-free pulse telegram superimposed on a power network by a remote control transmitter of a known type of the type according to I'ig. 2 becomes one

Receiving part 3 supplied (see. Fig. 1). The input terminals 4 and 5 of the receiving part 3 are connected to the neutral conductor O and the phase conductor P of the high-voltage network 2, respectively. The pulses with the remote control frequency. / are separated from the mains frequency f _s in the receiving part 3 by selection means and finally converted to direct current or direct voltage pulses, which ideally have a shape according to FIG. 3.

The pulse sequence appearing at the output 6 of the receiving section is now preferably subjected to an amplitude evaluation and pulse shaping. This can preferably be done by means of a differential amplifier 7, which fulfills both of the tasks mentioned. For the amplitude evaluation, the differential amplifier 7 is given a reference voltage U 1 at its inverting input 8 which corresponds to the threshold voltage desired for the amplitude evaluation. The reference voltage U 1 is derived from a preferably stabilized DC supply voltage L /, which is fed to a terminal 11, by means of a voltage divider from the resistors 9 and 10. educated. The pulse sequence occurring at the output 6 of the receiving part 3 is fed to the non-inverting input 13 of the differential amplifier 7 via a line 12. Always and as long as the signal at the input 13 exceeds the reference voltage U 1, an output voltage determined by the supply voltage of the differential amplifier 7 appears at the output 14 of the differential amplifier 7; During the rest of the time, the logic signal 0 is present at output 14. This results in a pulse train at output 14 when a pulse telegram is received. As a result of the settling time of the selective part of the receiving part 3, as well as the delay due to any integration elements provided and also due to the response of the differential amplifier 7 only when the threshold specified by the reference voltage U _{r is} exceeded, there is a delay time T ₁ between the received pulse train and the Pulse sequence at the output 14 of the differential amplifier 7.

The pulse sequence occurring at the output 14 of the differential amplifier 7 is fed to a shift register 16 via a line 15. The shift register 16 has just as many stages as the pulse telegram information bit, ie four in the present exemplary embodiment. The four stages 17, 18, 19 and 20 of the shift register 16 can be constructed in a known manner. In blocks 17 ... 20 of block diagram 1, the designations C, J. K, Q and Q customary for such modules are entered so that their interconnection can be seen. The I, line 15 leads on the one hand to the J terminal of the first stage 17 and on the other hand via an inverter 21 to the K terminal of the first stage. The second, third and fourth stages are connected in cascade in the usual manner, with the clock inputs C of all four stages via a line 22 with a clock 23 verun the.

In order to cinzulesen the pulse sequence ugefuhrtc via the line 15 to the shift register 16 into the same. must feed the clock inputs (of the shift register 16 via the line 22 suitable shift pulses) These shift pulses are generated in the clock 23 Fine detailed description ik-s l.tktpcrxis 23 follows later The clock 23 wml as a reference frequency For this purpose, the input terminals 24 and 25 are each connected via a line 26 or 27 to the neutral conductor O and the phase conductor P of the high-voltage network 2. In addition, a further input terminal 28 of the clock generator 23 is connected via the line 15 to the The pulse sequence appearing at the output 14 of the differential amplifier 7 is fed in. The line 22 from the clock inputs C of the shift register stages 17 ... 20 is connected to a first clock output 29 of the clock generator 23.

From a (J output of the first stage 77 of the Shift register 16 leads a line 30 to one

'5 Input 31 of the memory 32. In an analogous manner, the second, third and fourth stages 18 or 19 or 20 of the shift register 16 are each connected to an input 36 or 37 or 35 via a line 33 or 34 or 35. 38 of a second or a third or fourth memory 39 or 40 or 41 are connected. All clock inputs C of the memories 32, 39. 40 and 41 are connected to a further clock output 43 of the clock generator 23 via a line 42.

The start bit of a pulse telegram sets the clock 23 in motion. The clock generator 23 then generates five clock pulses. which from its first clock output29 via line 22 to the shift register 16 arrive, as a result of which the reading is carried out via the line 15 to the shift register 16

3 "Pulse sequence completed. After completion of the read-in process the clock generator 23 generates a memory command pulse at its second clock output 43, which is fed via line 42 to the (inputs of memories 32, 39, 40 and 41. As a result

The memories 32 or 39 or 40 or 41 accept this memory command pulse via their /) inputs 31. 36. 37 and 38 the Sehk region levels 17 and 18 and 19, respectively, at the (^ -exit of your trains or 20 pending information. As a result, the shift register 16 becomes necessary for receiving a new incoming pulse telegram free again.

The storage of the read into the shift register 16 Information in the memories 32, 39, 40 and 41 is useful because during the reading process any new pulse telegram received into the shift register 16, the information of the previous pulse telegram is lost. Since the reading process, for example, with a Cycle time of (), (> seconds takes place, i.e. relatively big slowly, this would be done until the reading process is finished. possibly to glitches in the display devices of the signaling device lead especially to the flickering of indicator lights.

The information, logical signals 1 and 0, which are present at the Q outputs 44, 45, 46 and 47 after the memory command has been accessed from the exit 42, is transmitted via the lines 48, 49, 50 and 51 to the coding inputs 52, 53, 54 and 55 to an evaluation device 56, for example designed as a diode matrix. From each of the mentioned deco diereingängc cmc vertical contact tracks 5 'or 58 or 59 or 60 leads to horizontally arranged! Contact tracks 61 or 62 or 63 over. At selected points of intersection of the vertical and horizontal contact paths, a specific configuration regulation can be implemented by inserting diodes 52 'or 53' or 54 'or 55'. Such an arrangement known as a diode matrix is used in bc

known way for decoding the received pulse train or that output from the stores 32 or 39 or 40 or 41 to the ejection device 56 Information.

The result of the appearing at the decoding inputs 64, 65 and 66 of the evaluation device 56 Decoding represents a combination of control commands for the display elements 67 or 68 or 69, for example lamps associated with certain direction arrows 70, 71 and 72.

For the actuation of said display organs or for turning said lamps on the decoder exits 64 and 65 and 66 the signals appearing, for example, via a respective resistor 73 or 74 or 75 depending on a switching transistor S ¹ 76 or 77 or 78 fed. In the collector circuit of each of these switching transistors 76 or 77 or 78 a relay 79 or 80 or 81 is arranged, which with its normally open contact 79λ or 80a or 81 'closes a supply circuit associated with the display elements 67 or 68 or 69 . The supply circuits of the lamps provided as display orgcint in the present embodiment can be connected to the phase conductor P and the neutral conductor O of the high-voltage network 12, for example, via the working contacts mentioned.

Fig. 2 shows an example of a pulse telegram with a start bit in a first Zcitintcr- \ all I and four; Necessary information bit in the following intervals II ... V. In the ideal case, the receiving section 3 would have a pulse train at its output 6 deliver according to FIG. 3.

A series of diagrams is shown in FIG. The diagram α shows once again the pulse sequence according to FIG. 2 with the remote control-frequency signal voltage U ₁ as the ordinate. The intervals I ... V together result in the time span 7.

Diagram b shows a curve of the output voltage 4 from a receiving part 3 as it is achieved in practice. The pulse sequence according to Diagranim /> is delayed by the anticipated delay time τ in relation to the intervals I ... V. The pulse train according to diagram b lies within the time span 7 ″. Diagram b also shows the level of the reference voltage U. If this reference voltage (; appearing pulse train, which is shown in the diagram <.

The clock generator 23 ei α ugt at its output 29 a pulse train according to diagram d. In each case about a fixed Verzögcrungszeit τ_ after the start of the pulse sequence shown in the diagram (associated intervals IV is. Produced at the output 29 a falling edge / h \. This falling pulse edges represent the Schtebcimpulse. Soft for insertion dt r pulse train from Alisgang 14 of the Differentialver st .irkers 7 in the shift register 16 are required

Diagram c shows the course over time of the pulse sequence appearing at the output 43 of the clock generator 23. With the first rising edge to Zcit-P'ifk ".""Of diagram r, a flip-flop is set in clock generator 23, with the negative edge / -" in diagram e generating! will. At the end of the time period T at time t _h , the clock generator 23 generates a rising edge F _h at its output 43. which acts as a synchronizing error pulse for feeding the information at the outputs 17, 18.19 and 20 of the shift register K into the memories 32, 39, 40 and 41. The signal course at the output 43 of the clock bit 23 is shown in diagram c . How this memory command pulse is generated will be louder later in the description of the clock generator 23 in detail.

On the basis of FIG. 5, the task that the clock generator 23 has to fulfill, its structure and its mode of operation are explained in more detail. The clock generator 22 has the following tasks: After the start bit of a pulse telegram arrives at the output 14 of the differential amplifier 7, a clock sequence of füm shift pulses for the shift register 16 must be output at the output 29 (see FIG. 1). If the cycle time of the pulse telegram, i.e. the duration of each of the intervals I to V (see Fig. 4), for example (50 milliseconds, then the shift clock must also have a rhythm before 600 milliseconds. However, the start of the shift clock sequence is, as mentioned, preferably delayed towards the beginning of the start bit, in our example by 200 milliseconds. This delay is provided so that two: pulse edges, one from the pulse telegram and one from the clock sequence, do not coincide Pulse sequence at the output 14 of the differential amplifier 7 is not necessarily coherent with the audio-frequency pulses on the phase conductor P or at the output 6 of the receiving part 3, since, for example, signal fluctuations can cause the threshold value at the input of the differential amplifier 7 to be reached earlier or later beneficial to the existence of an impulse of the impulse telegra mms cannot be determined immediately at the beginning of its associated interval, but preferably within this interval, for example after approximately one third of the interval time. For this reason, a delay τ of 200 milliseconds was chosen in the present example.

If the said clock sequence of five shift pulses have been delivered at the output 29, si the clock generator 23 still has to emit a storage command pulse at its output 43.

The clock generator 23 has a flip-flop 100. The flip-flop 100 via a line 101, the positive supply voltage I at its Datencingang 102 supplied from the terminal 11 (see FIG. FIG. 1] as a logical signal 1 Fin clock input 103 of flip-flop 100 is connected via line 104 to the input terminal 28 of the clock generator 100 is connected, by means of which the flipflop 100, the Diffcrentialverstärkers 7 is supplied (see. Fig. 1) occurring pulse train at output 14. Upon arrival of the start bits of the flip-flop is set 100. This means that whose output 105 , which carries the inverse output signal, goes to logic 0. The flip-flop 100 remains in this position until its I "" switch input 106 is supplied with a clear pulse via a line 107.

23, at the input terminals 24 and 25 of the clock which are connected to the neutral conductor O and the Phasenleitcr P of the power network 2, a voltage divider consisting connected from the resistors 108 and 109. By means of this clamping voltage divider network voltage with the frequency f ^ reduced to a value that is beneficial for the electronic components of the clock rate at 23

The one occurring at the voltage divider point 110 AC voltage is generated via a diode 111 at a resistor 112, which is a Zener diode 113 connected in parallel, positive pulses. These positive ones Pulses are combined with a Schmitt trigger via a resistor 114 to an input HS NAND gate 116 supplied.

A second input 117 of the NAND gate 116 is connected to the non-inverting output 119 of the flip-flop 100 via a line 118. As a result of this connection with the flip-flop 100, the NAND gate 116 now sends mains-frequency pulses from its output 119 via a line 120 to an input 121 of a counter 122 only during the duration T (see FIG. 4) of a received pulse telegram reach.

The counter 122 is used to generate the mentioned cycle time of 600 milliseconds in our example, from the mains-frequency pulses fed to it. These line-frequency impulses follow one another with a 50 Hz mains voltage with a rhythm of 20 milliseconds. In addition, as mentioned earlier, the beginning of the first clock pulse can be delayed by τ, in our example by 200 milliseconds.

In a divider 123, 10 pulses or falling pulses from the NAND gate 116 are initially generated Counted pulse edges. The tenth pulse or the tenth falling pulse edge can be seen on one Output 124 of divider 123. This tenth pulse is an input 126 via a line 125 three-stage, made up of three flip-flops 128, 129 and 130 asynchronous counter 127 supplied. The flip-flops 128, 129 and 130 are via delay elements, represented by inverter groups 131 and 132nd coupled. The designation of their connections that is customary for such components is given in the form shown in FIG. 5 these asynchronous counter 127 representing blocks entered. This results in the required circuit arrangement for the construction of the asynchronous counter 127. The signal fed to the input 126 also becomes the A 'input via an inverter 133

134 of the first flip-flop 128 of the asynchronous counter 127 is supplied. The pulses at the output 124 of the first divider 123 form after their inversion and delay in two inverters connected in series

135 and 136 the shift clocks for the asynchronous counter 127. These are over a line 137 the Clock inputs 138, 139 and 160 of the flip-flop 128, 129 and! 30 are supplied.

The pulse appearing at its output 124 after the first 20 input pulses of the divider 123 is fed to a clock input 142 of a D-flip-mop 143 via a line 141. The data input 146 of the D flip-flop 143, a positive voltage from a terminal 11 becomes a logical 1 signal fed. The flip-hop 143 is set by the 20th pulse and gives one of its inverted output signal leading output 144 from a first shift clock, which via a line 145 to the Output terminal 29 of the clock 23 is performed From the inverted output 147 of the flip-flop 130, a cancel signal is then sent via a line 148 the delete input 149 of the D flip-flop 143 supplied. so that this is reset again.

Subsequently, after every W) 0 milliseconds, a switching cycle appears at the output terminal 29 The switching clocks at terminal 29 are also connected to a clock input 151 via a line 150 5-bit counter 152 supplied. A clear input 153 of the 5-bit counter 152 is connected to the line 118. As a result, the 5-hit counter 152 is initially cleared at the beginning of a pulse telegram. After 5 shift clocks have been fed in, it emits a logic 1 signal at its output 154. This signal logic 1 is inverted in an inverter 155 so that a logic 0 signal as a cancel signal over the line

i "107 is fed to the D-flip-floop 100 the D flip-flop 100 is reset after the 5 shift clocks at terminal 29, and on A positive pulse appears at output 105, which is transmitted via a line 156 to output terminal 43 of the

Clock 23 is supplied. In addition, this is fed to the delete input 157 of the first divider 123. At the output terminal 43 appears a pulse train according to Fig. 4, diagram e, and the divider 123 is at the beginning of each interval in its output

* ° initial position set back.

In the present embodiment it was assumed that as a display element 67 or 68 b / w. 69 lamps are used, each with a directional arrow 70 or 71 and 72 are assigned. Self-

* 5 can also be understood by other display organs, such as Electromagnetically actuated direction arrows, etc. are provided.

While, as mentioned earlier, it is known by a remote control command, which can also be transmitted in coded form, for example a to effect a certain position of the display elements in a remote signaling device, takes place after present invention, the actual control of the Display organs according to a different principle, which

is explained in more detail below for a simple case.

For example, if there are two multi-storey car parks A and B available in a region, the following are all conceivable:
1. Parking garage A still has free spaces. Parking garage B

still has free places.
2. Multi-storey car park A is occupied. Parking garage B still has free spaces.

-V Car park A still has free spaces. Car park B is occupied.

4. Multi-storey car park Λ is occupied. Parking garage B is occupied The occupancy status of parking garage Λ can be printed out by a first parameter a, namely by a first binary signal, for example 1 for free and 0 for occupied, and the status of parking garage B by a second parameter h or by a logic signal or 0. ^p

At a traffic junction X is now a Signaling device arranged according to the present invention. Let us now assume that at the access to the mentioned junction X d.is parking garage A can be reached by driving to the left and the car park B by driving to the right It is also possible to drive straight ahead The signaling device at the traffic junction X now has three directional signs in addition to the hirkicrungshinwcis P. 70, 71, 72 and that the directional arrow 70 to the inks, the directional arrow 71 straight on: the Richtiingspfcl 72 directed to the right Each of these direction arrows is a lamp 67 or 68 or 6 «) (^ l I ig. 1) assigned.

s .si now g ß expedient _{it. In} the first case mentioned

the direction arrow 70 and the direction arrow 72 light up to leave, as both when driving to the left and when driving to the right a / ur Zeil Parking garage with free spaces can be reached. In the second case, where only car park 13 has free spaces, you can now only light up the directional arrow 72, because only when you continue to drive There is a free parking garage on the right. In the third case, where only multi-storey car park A still has free spaces, If only the direction arrow 70 lights up, because a free parking garage can only be reached if you continue to the left. Finally, in the fourth case, where Both multi-storey car parks A and B are occupied, only the directional arrow 71 can be lit to indicate the road users not to unnecessarily lead to the already occupied multi-storey car parks A and B.

As can be easily seen, this results from the opposite direction of approach to the traffic junction X is an opposite display with respect to the left and right directions. Also from others Directions or at other junctions and branches in the region concerned there are individual needs for the most advantageous directional display in each of the four cases mentioned.

The present invention now allows in a very simple manner with simultaneous supply of the same information, ie the parameter λ (occupancy of parking garage A) and parameter /) (occupancy of parking garage B) to all signaling devices provided in the region, these nevertheless work individually adapted to the local conditions allow. This is due to the fact that each of the various signaling devices evaluates the two parameters α and h supplied to it and possibly others in accordance with the needs resulting from their local conditions in a manner independent of the other signaling devices.

Further parameters c and d can relate, for example, to the traffic condition in the relevant region. For example, there is no point. To direct road users to a car park D if the access to this from the relevant location of a signaling device is obstructed by standing columns. It is possible to use a parameter a. b, c etc. to be fed separately or jointly to a signaling device. However, it is particularly advantageous to accommodate this information in a pulse telegram according to FIG. 2 or 4. Such a pulse telegram is then preferably fed to all signal devices in a region simultaneously. This feed now takes place preferably with known means of network overlay technology. as it is known from the so-called ripple control over power networks. Since each of the signaling devices I (see. Fig. I) is connected to the respective high-voltage network because of the necessity of their lighting, the above-mentioned parameters can be used, for example, as tone-free pulses with the aid of network overlay technology with very little effort
gnalc can be transmitted to the signaling devices via the power grid. This eliminates the need to draw special signal lines, which in urban conditions can only be carried out with great difficulty and at considerable costs. B. Funkkanäie.

Which display options are available with one information bit other than the start bit result in the total pulse telegram and wi <this possibilityeii. expressed by the various the possible codes that can be assigned to them are shown, for example, in the table in FIG.

As can be easily seen, for example, auel the lighting of the parking sign P is coupled with the switching on of the lamps 67 or 68 or 69 will.

To form the parameters α and b, which, for example, determine the bending state of parking garages

• 5 occupancy counters, which are usually provided anyway, are used. It can be advantageous to issue an occupancy for the parking garage in question when the occupancy rate is 95 '', for example, because there is little point in assigning additional road users to a parking garage from another catchment area that is about to be fully occupied.

Other parameters, for example c and </, which relate to the traffic situation, can for example be issued by a Polizci control center. As mentioned, such parameters can be used by the signaling devices can also be sent individually. However, it is more advantageous, for example, in a substation the electricity supply, which supplies the region concerned with electrical energy, the to prepare their supplied parameters in a known manner into a coded pulse telegram and feed this to the signaling devices by means of the known network overlay technology. The transmission the parameters from the individual parking garages or from the police control center Parameters originating from this substation of electricity supply can also be used the network overlay technique.

The application of the invention is not limited to the example described with parking garages. It can also contain other information, such as recommended speeds, mandatory or blocked Exit directions from highways, prescribed or blocked driving directions to major events, etc. with the help of the invention for display to be brought. Finally, it is also possible to use the Invention in other areas of signaling, such as rail-bound traffic.

apply accordingly.

In a preferred further embodiment of the invention, the evaluation device 56 is adjustable Diode matrix formed. Such an adjustable diode matrix is, for example, a crossbar distributor with connectors each containing a diode. But it is also possible. Diode matrices to be carried out using printed circuit technology, these printed circuits are designed as plug-in cards. Any such plug-in card yields thereby a certain link between the individual pa ramcler. By simply plugging in or switching on Another diode matrix or plug-in card can be used to program a signaling device 1 adapt the described type to the respective requirements

In addition 5 sheets of drawings

Claims (17)

Patent claims: I. Procedure for controlling a traffic control system with a plurality of signaling devices, characterized in that for Location of each signal device at least two parameters that are the same for all signal devices are transmitted by signals, and that at the location of the signaling device from the received Parameters and control signals from location-related information stored in the signal device are formed for the display elements of the signaling device. 2. The method according to claim 1, characterized in that the parameters by a power network superimposed signals are transmitted to the location of the signaling device. 3. The method according to claim 1, characterized in that the parameters transmitted by signals are temporarily stored. 4. The method according to claims 1 and 2, characterized in that clock pulses for the temporary storage of the parameters transmitted by the signals derived from the network frequency will. 5. The method according to claims 1 and 2, characterized in that the parameters in one encoded pulse train are transmitted. (I. Method according to Claims 1 to 5, characterized in that a pulse sequence obtained from the signals transmitting the parameters is entered serially into a shift register and fed from this in parallel, possibly via a memory, to an evaluation device. 7. Device for performing the method according to one or more of the preceding Claims, characterized by a controllable signaling device (1) which has a receiving device (S) for at least two parameters transmitting signals is assigned, as well as one of the receiving device (3) connected downstream Evaluation device (56) for generating criteria for the automatic control of display elements (67, 68, 69; 70, 71, 72) of the signaling device (1). 8. Apparatus according to claim 7, characterized in that the receiving device (3) is connected to a power network (2). y. Device according to claims 7 and 8, characterized by a receiving device (3) which, as selection means, has at least N-path filters having. 10. The device according to claim 7, characterized in that that the receiving device (3) is followed by a device (7) for amplitude evaluation and pulse shaping. 1 1. Device according to claim 7, characterized in that that the receiving device (3) is followed by a shift register (16). 12. Device according to claims 7 and I 1, characterized in that the shift register (1.6) stores (32, 39, 40, 41) for temporary Storage of the parameters transmitted by the signals are connected downstream. 13. The device according to claim 7, characterized by a diode matrix as an evaluation device (56). 14 Device according to claim /, characterized by the lifting device (56) connected switching devices (76,79, 79a; 77 80,80a; 78, 81, 81 «) for closing and opening of supply circuits of display elements (67, 70; 68, 71; 67, 72). 15. Device according to claims 7 and 1 "», characterized in that the diode matrix is designed to be adjustable. 16. Device according to claims 7 to 13, characterized in that the diode matrix is designed to be pluggable. 17. Device according to claims 7 and fs. characterized in that for generating shift pulses or storage command pulses a clock generator (28) connected to the power network is provided.