DE2007335B2 - DEVICE FOR CONTROLLING TRAFFIC LIGHT SIGNALS - Google Patents

Description

work the same cycle and synchronization jmpujse, but different shift signals can be supplied are that each area controller is a device to generate further synchronization pulses, the opposite of the first-mentioned Synpjiranisierini pulses are shifted by the shift time determined by the shift signal, and one of the further synchronization pulses of each of the Local control units supplying device contains that each of the local control units assigned to it Controls traffic signals on the basis of the additional synchronization pulses it receives from a the range control units has received that the device for generating further synchronization pulses a register for storing the shift signal that it receives from the central control unit Counter that counts the cycle pulses emitted by the central control unit and the other synchronization pulses outputs when it has reached predetermined count values and contains a circuit arrangement, which controls the counter so that the time between the occurrence of the first mentioned and the next Synchronization pulse is equal to the offset stored in the register.

After that, a relatively large area is divided into several areas, each with one Area control unit is provided. which coordinates several local control units within this area controls. Each local control unit controls the traffic signals of a traffic light system. All Area control units are controlled by a single central control unit. The central control unit performs the same cycle times for all area control units and synchronization pulses. Leads to the coordinated control of the traffic signals of neighboring areas the central control unit for different area control units "! different shifts in neighboring areas. Each area control unit generates Synchronization pulses that are opposite to the synchronization pulses received from the central control unit are offset by the shift time prescribed for the area control unit. and performs this Synchronization impulses to the local control unit. the dim area controller is assigned so that each local control unit the traffic signal ·; its own traffic lights depending on controls these synchronization pulses. The fact that different areas are appropriately chosen shift marks can be assigned, the traffic signals of the traffic lights in the larger Area depending on the facts Control traffic conditions in the individual smaller areas in a coordinated manner.

This facility is particularly simple insofar as only one parameter is influenced by the central control unit, namely the cycle shift The central control unit can therefore essentially consist of a clock pulse generator, which emits pulses cyclically at predetermined times, and a simple arithmetic unit which numerically determines the shift depending on the interrelationship of the field control units and overlays them in the respective register. With the help of the counter and the associated circuit arrangement, the numerically specified shift value is converted in a simple manner into a time shift of the synchronization pulses emitted by the counter, without changing their time relation.
The invention is described below by hand

Drawings described in more detail, in which a preferred embodiment is shown.

1 shows a schematic block diagram of the entire device according to the invention;
Fig. 2 provides a detailed block diagram of a

ίο Beretchssteuerwerk;

Fig. 3 shows the time course of various signals that are used in the circuit arrangement according to Fig. 2 occur, and

F i g. Figure 4 illustrates another embodiment of the range controller according to Fig. 2 in the form of a block diagram represent.

Fig. Ί only represents a control device for represent two areas, but in practice as many area control units can be provided as areas are in place, with all the range control works in a similar manner from a single central Control unit 1 can be controlled. One of the two areas contains two local control units 4 and S and the other three local control units 6. 7 and 8. However, each area can have so many local Control units included as required. The local control units 4 and 5 are controlled by one Area control unit 2 controlled, and the local control units 6, 7 and 8 are controlled by the second area control unit 3 controlled, in practice z. B. the entire area of a city in so many areas be subdivided as required, their local ones each arranged in different places Control units in each area can be controlled by an area control unit.

A traffic information sensor 9. 10 is provided in each area to monitor the traffic conditions notices in this area. The area control unit 2 controls the local control units 4 and 5 in a coordinated manner according to the gaps and displacements that the area control unit as a function of the determined by the sensor 9 received traffic information, and the area control unit 3 controls the local Control units 6 and 7 coordinated according to their gaps and shifts from the area control unit 3 can be determined as a function of the traffic information received from the sensor 10.

The area control units 2 and 3 transmit the

_So vo "the sensors 9 and 10 received traffic information to the central control unit 1 determines the cycle of all traffic signals in the system, and the displacements of the area control units 2 and 3. FIG.

When the central control unit 1 has set the Signalzvklu '. it generates corresponding pulses (hereinafter referred to as "cycle pulses") with a frequency that is inversely proportional to the cycle length , 6. 1 and 8,
In addition to the cycle pulses, the central

Control unit 1 the area control units Pulses ztt, which are syrichronisierl with each signal cycle are (these Wetdeii continue to be »SMC-Syilcilföriisierimpttlse« called) and in their clock the areas ^

Steuerwerkä Arbeiter ^ which is described in great detail. The central control unit also carries out signals "zu (weiiefhih ÄSMC-Vefsehiebesigiiale" genaniil) ₍ which prescribe various shifts that are carried out by the various controllers. also called fC synchronization pulses), with respect to which the SMC synchronization pulses are offset by the shift time prescribed by the range control unit 2, and feeds the I.C 'synchronization pulses to the local control units 4 and 5 Area control unit 3 generates LC synchronization pulses, compared to which the SMC synchronization pulses are shifted by the different displacement times prescribed by area control unit 3 and feeds these IC synchronization signals to the local control units ή to 8. The local control units 4 and 5 in the first area and di e local control units 6 to 8 in the second area are therefore not controlled by the same synchronizing pulses, but by synchronizing pulses which are shifted by different amounts compared to the SMC synchronizing pulses, so that the traffic signals in the two areas are controlled in a coordinated manner.

FIG. 2 shows details of the circuit arrangement of each area control unit according to FIG. 1. The central control unit has three connections C1. Ci and C3 cycle pulses with different frequencies? In the following, the line or a connection and the signal passed over it are also denoted by the same reference number. The signal Cl has a frequency of 100 pulses per signal cycle, the signal C2 has a lower frequency of 100 pulses per 1.25 signal cycles and the signal C3 has a higher frequency of 100 pulses per 0.875 signal cycles. The signals Cl. C2 and C3 are each fed to an input of AND gates 11, 12 and 13. A tristable circuit 25 feeds its three output signals Bl. B 2 and B3 to the other input of the AND gates 11, 12 and 13, respectively. which will be described in more detail.

The output pulses of the AND gates 11 to 13 are fed to a pulse counter 15 via an OR gate 14. The counter is designed so that every time it has counted 100 pulses of the pulses supplied to it. is reset to zero and at the same time emits a signal via line 500 and each time it has counted 4. 50 and 90 pulses, emits a signal via lines 504, 550 and 590, respectively. In other words, the counter 15 emits a signal via the lines 500, 504, 550 and 590 after a time of 0, 4, 50 and 90 ⁰ O of the signal cycle duration has elapsed. These output signals represent the LC synchronization signals which are fed to the local control units which are controlled by the area control unit.

The SMC shift signal generated by the central control unit is fed to a terminal 50 in binary decimal form. The encoded signal 50 is stored in a 7-bit register capable of storing decimal numbers up to 100. The already mentioned counter 15 is designed similarly to the register 16 and has seven output lines. The fermenting signals corresponding to the seven bits of the register 16 become an incidental 1? Iug'efühft, to ' dct also the seven ¹ outgoing members of voter 15 lead .. Öid Schälfürig ± 1 compares the value in register 16 with the number

lörstand des / Sähiefs 15 and generates a signal on a line "0 $ if both; Überefeinsfimnien.- The = This signal ÖS forms" the one input signal of four i'ND-Geders 21 to 24.

The central control unit also has connections

ίο / V / 00. M 04. · ν / 50 and / V / 90 SMC synchronization pulse 7u. The signal Λ700 is a pulse that is generated each time after a signal cycle has elapsed, and the signals M 04. / V / 50 and / V / 90 are pulses that are _{generated each time after 4. 50 and 90 "n of} each signal cycle after the generation of the signal, WOO. These signals Λ- / 00 to / V / 90 are shown in Figures 3 () to (e) , respectively.

The signal Λ / 04 is fed to the set input of a flip flop 18, whose reset input is fed to the signal / V / 90. Therefore, the flip-flop 18 remains during 4 to 90 "ο the duration of a signal cycle set. The setting and Riicksetzausgangssignale of flip-flop 18 3 (0 and (g) are shown in FIGS.. Pas signal / V / 50 to the set input is a Flip-flops 19 are supplied, the reset input of which is supplied with the signal MOO. The flip-flop 19 therefore remains set for 50 to 100 "ο the duration of a signal cycle. The set and reset output signals of the flip-flop 19 are shown in FIGS. 3 (Vi) and (/ ) shown.

The set output signal of the flip-flop 18 is fed to a second input of the AND element 21, and the set output signal of the flip-flop 19 is fed to the third input of this AND element 21. The AND gate 21 therefore only emits a signal. when the signal OS is generated by the coincidence circuit 17 during the time from 50 to 90 ° 0 of the duration of one signal cycle, as shown in FIG. 3 (/) is shown. The following are periods of time such as

"The time span from 50 to 90" 0 the duration of a signal cycle "simply called '> 50 to 90" 0 time span ". The reset output signal of the flip-flop 18 is fed to the second input of the AND gate 22. The AND gate 22 therefore only emits a signal. when the signal OS is generated during the 90 Ns 100 ° o period or the 0 to 4 ° o period of a signal cycle, as shown in FIG. 3 (k) . The set output signal of the flip-flop 18 is a second input of the AND-GHe-

of the 23 supplied, while the reset output signal of the flip-flop 19 is supplied to the third input of this AND gate 23. The AND gate 23 therefore gives, as shown in FIG. 3 (I) can be seen. ^ i only emit a signal if the signal OS during the

4 to 50 ° 'o period of a signal cycle is generated ± Finally, the reset output signal is generated of the flip-flop 18 is fed to a second input "of the AND gate 24, while the set output signal of the flip-flop 19 is fed to the third input.

The AND element 24 therefore only emits a signal, as shown in FIG. 3, (m) can be seen when the signal OS is generated during the 90 to 100% time span of a signal cycle.

The output signals of the AND gates 21 to 23 are each one of three inputs of the unstable Circuit 25 supplied. When the output signal of the AND gate 21 is an input F of the Circuit 25 is supplied, this outputs on a line

direction Bl. eiw signal äbj when the air output signal switches. During the 90 to lOO'Vo ^ Zeitspanrie are UNDföiiedes 22 ei'ilem S input of the circuit 25, the AND gate 22 outputs a signal) so that the äüszugefunff, · outputs it via a line Bl a gangssignai III of the circuit 25 AND gate 12 signal from, Urid we'firi 'the Aüsgarigssigiial of the AND- is fed. Diss causes; that cÜÖ impulses (ti element 23 a! input T of the circuit 2a pulls 5 the counts · 15 via the AND element 12 and that leads; wSi4 gives this' via a line ß3 a Si-OR element 14 is shown however the % i \ a \ ab. · It is now assumed - that the input signal .57 * is still fed to the counter 15 ", process .Ϋ of the circuit 25 after Fl g; 2 a signal prevents this, that the pulses Gt is fed to the counter 15 so that this is via the line Bl a further switch. However, when the 90 to lO0 ⁿ o-time oN signal ίο. span expired. allows the signal V / (M), the Si -

The output signal ST of the AND element 24 will signal 57 ″ disappear, so that the counter 15 is now supplied with an input of the OR element 14. Thus, the cycle pulses C 2 begin to count. Di as long as the output signal ST dem Counter 15 over a cycle of normal duration in each case 100 cycle the "OR gate i4 is supplied, the counter impulses Cl will be generated, the counter 15 is not incremented after 15, even if the counter 15 13 expiration of each normal cycle back to zero from any of the AND gates Π up to 13 pulses. The difference between the SMC Synzufeed. chronisierimpuls V / 00 and the LC synchronizer

It is now assumed that the central control pulse 500 is therefore the same as the new one in the register 1, depending on the shift stored in it by the guide 16. Traffic information 20 supplied by this eyes 9 and 10 is generated by the counter 15 as long as LC-Syncrro has made a decision. that the shifts in the denizing pulses must be changed on the basis of the new shift, and consequently until the shift is changed again.
Register 16 of area control unit 2 or 3 the Si If the signal 57 "in the 0 to 4" »time span

gnal SO. that represents a new shift that occurred to. gives the t'ND signal 22 via the I.ei storage. At this moment a signal is sent to the ß2 device. whereupon the counter 15 with counter 15 begins counting the pulses C 2 through the normal cycle pulses C2
weiterge ^c chaltet. which to him via the AND gate 12 is accepted. that the coincidence circuit 17

and the OR gate 14 are supplied. If the signal OS has reached the value of the signal cycle generated during the 4 to 50 'o period of time, the counter reading of counter 15 has reached the value. then the AND-hat leads. which corresponds to the new element 23 stored in the register 16 at the input T of the unstable circuit 25 shift value, the coincidence gives a signal. thus the circuit 25 sends a signal to the AND circuit 17 via the line OS. As member 13 supplies a signal via line ff3, as already mentioned, the result of this is that the counter 15 counts the cycle pulses C3 supplied to it via the synchronization ratio between the signal OS and OR member 14, the SMC synchronizing pulses. 35 Since the frequency of the pulses C 3 is 12.5 "<> higher V / 04, V / 50., V / 90 and Λ / 00 than the frequency of the normal pulses is Γ2. is the opposite That existed before the new time, which the counting 15 for counting lOnimpul shift was stored in register 16, needed to change C 3 to 12.5 "ο shorter than the normal changes. Duration of a signal cycle. Hence the Signa!

Assume that the OS signal is active during 40 OS. when the shortened signal cycle has been generated three times at most 50 to 90 "η time period of the signal cycle is repeated. in the 0 to 4 ° o time. Then the AND gate 21 generates in the period of the signal cycle. Syn-Ausenblick. In which the signal OS is generated, a chronisierimpulse is determined. Or if the \ er-sianal. The signal cycle shortened to the input F of the tristable circuit is fed to the input F of the tristable circuit repeated four times at most, so that the output signal BX is 45, the signal OS appears in the 90 to 100 "or L" ND element 11. The counter 15 time span of the normal signal cycle counting cycle pulses, since the frequency of the signal MOO ura the new shift that these pulses Cl by 12 _in.! / o lower than that of _e stored ^ register 16 5 °, moved with other normal cycle pulses C 2,.? the counter Sö-Wbr ten _{r of} the counter 15, the LC-Syn-15 now generates a 12.5 ⁰ O longer time for counting chronizing signals on the basis of the new shift 100 impulses that it received via the terminal C1.

leads to the counting of 100 impulses, the LC-Synchro-nisiersignale 500, 504, 550 and

be fed to him via the connection C 2. Nut 590 are the other words belonging to the area control unit, the duration of a signal cycle is now supplied to the local control units. The area 12.5 ° longer than the duration of a normal control unit sets a shift for each of the local signal cycles. If then this extended signal lent control units firmly on the basis of the range cycle is repeated three or four times at most. Control unit received shift and LC-Syn appears the siznal OS in the 90 to 100 ° Ό- or chronisiersignale each local control unit generates 0 to 4 ° / o-time span of the normal duration of a So its own synchronization signals to control the signal cycle. the traffic signals assigned to the terminals M 00 to M90 in a manner known per se, supplied to M90,
true istl In Fig. 4 is a modified embodiment

If the signal OS has occurred in the 90 to 100 »0 time span shown in the area control unit according to FIG. 2, the AND element 24 outputs 65. Here the register 16 and the coincidence shell are the line ⁵ ST and aas OR -element 14, a signal processing 17 of Fig. 2 by a circuit having a to the counter 15 from. as long as the counter 15, the register reversible replaced In Figure 4, the signal ST is supplied, it will not be forwarded jecigen parts, which correspond to those according to FIG

9 10

with the same designation marks, so that the 'Öe supplies more Substraktionsifnpulse, subtracts that

Inscription on those parts that differ from dericri register 35 die cited Stibslräktionsirripülsc

fiaeh Fig. 2 differentiate, can be restricted. From lOO,

the central control unit leads to a connection 50 the signal Ö5 becomes from register 3 £ j

a shift signal too. As in the case of FIG. 2, 5 is fed to an input of the AND gates 12 to 24,

the signal 50 binary decimal code. Simultaneously with, as in the case of the execution example according to Fig. 2,

When the signal 50 is supplied, the central office carries out exercise factoring impulses which are added to the register 35.

INeuefwefk a terminal 50C carries a further signal, those impulses are in front of it

fi. This signal 50C is, in contrast to the signal OR gate 14 via an AND gate 33 and that

I, a continuous signal. The two signals 50 io OR gate 34 are supplied. The Rückselzaus

(lid 505 If an AND element 32 is fed, the output signal of a flip-flop 31 is sent to one of the inputs

(Let the signal 50 be fed to a reversible register 35, output of the AND gate 33. The previously he ·

tfts a storage capacity of decimal numbers up to the mentioned signal50C is the set input of the flip

100 has, supplied via an OR gate 34, flops 31 supplied, while the output signal 50C

The new shift value, which is sent to the reset input of the flip-flop 31 in the form of the Si ij of the counter 15

CaIs 50 is issued by the central control unit, is supplied. As long as the signal 50C goes ahead

rd is stored in register 35. The register 35 is den, the AND gate 33 therefore does not emit a signal,

^ ηη only store the signal 50 if that and if the signal 500 has disappeared, there is «

; nal50C as a continuous signal via a line SRC register 35 subtraction pulses from the in:

is performed. When the values stored by the OR gate 34 are to be subtracted

day-level pulses to the register 35 without the control if, therefore, after the generation of the signal 500 dei

input signal SRC , the new pulls the new shift value stored in register 35:

tTer35 a value which the number of ORs has been reduced to zero, d. i.e. if the through

ied corresponds to 34 emitted impulses (after- the central control unit selected new shift

As soon as it has expired, signal 05 is generated. the

«Derive from the value stored in register35, mode of operation of the exemplary embodiment according to FIG. ')

is the stored value is zero, whereupon the Re- is easy to vcr- according to the explanation of FIG.

lister 35 emits a signal via a line OS. so that they are not described in more detail here

When the OR gate 34 becomes the register 35 after.

1 sheet of drawings

Claims (1)

007 335 J. Occurrence times of the second counter (35) Claims: emitted signal (OS) and. the first mentioned. Synchronizing impulses detective and a 1, device for controlling the traffic Ausgan.gssfenal dispensing device and a signals the in a larger area, which in several 5 depending on the last mentioned outrage smaller areas is divided, the output signal responsive and the frequency of the arranged Traffic light systems with several local Zyklrs-Steuerwerkeu supplied to the first-mentioned counter to control the traffic signal ^ contains impulses changing performance, of traffic lights in different places
are arranged in each of the areas, one ip each Area control unit for each of the areas to control the local control units in each
these areas is provided, and a central control unit, which all Bereichssteuenverken The invention relates to a device for CON-cycle pulses, sync pulses and cycle ₁₅ s of traffic signals in a larger Ge-shift signals supplies, characterized Bidding ge ISIN that in several smaller Areas is subdivided, shows that traffic light systems are arranged in all area control units, with several (2, 3) the same cycle and synchronization local control units to control the traffic impulses. But different shift signals signals of the traffic lights, which can be fed to different ones, that each area control unit has _two places in each of the areas, one device for each of the other synchronous area control units, which for each of the areas for sierimpulse (5 00 to 590) , which compared to the control of the local control units in each of these first mentioned synchronization pulses (MOO to areas is provided, and a central control / V / 90) by the shift signal (50) plant that all area steuenverken cycle., pulses, certain shift time are shifted, and 25 synchronizing pulses and cycle shift signals one the further synchronizing pulses to each of the feeds. There are numerous known devices which contain the direction that each of the local control signals of several traffic light systems within plants control the traffic signals assigned to it in a coordinated manner on a delimited area, the basis of the further signaling impulses 30 If the signals of the traffic light system are taxed by one of the area control units from one of the area control units, ύαΙΊ the device for generating is controlled in an ordinate manner and the signals of the traffic-related synchronization pulses are controlled by a register (16; traffic light systems in an adjacent area also 35) to store the shift signal (50) controlled by another area control unit that it receives from the central control unit (1), a 35 den and between these two area control unit counter (15). the front central control unit (I) ken there is no connection, there is a risk that the cycle pulses emitted (Cl, Cl. C3) counts that the traffic in the border areas between the and the other synchronization pulses emits, both adjacent areas are significantly disturbed if it has predetermined count values has reached, and so that the effect of the coordinated associations circuitry includes, that the Zäh- controls ₄₀ transport traffic signal control in the individual Bereiler that the time between the occurrence chen is questioned. Ten of the first mentioned and the other syn- Man has therefore already discussed facilities chronising impulses equal to that in the register ("Straße und Verkehr". No. 1.15. January 196, p. 23 stored shift is. up to 25). where the area control units by a 2, control device according to claim 1. characterized 45 superordinate and central control unit so controlled that the register (16) and that is to be that all areas traffic-dependent co-counters (15) a coincidence circuit (17) are after- ordained. A practically usable and wired one. which emits an output signal (OS). A particularly simple device of this type has so far not become known when the count of the counter (15) is equal. Even if one can assume that the control unit is the shift value, which is stored in the register (16). and the circuit arrangement includes a range control units for coordinated control of the difference between the / \ uftrittszeitpunk- cycle pulses. Synchronizing pulses and cycles of the output signal (C) S) would have to supply coincidence shifting pulses, there are numerous possibilities here, however,! Means and how this signal-generating device as well as one is influenced, and one that is special in terms of device technology. .hherigigkeit Of the output signal the simple type of influence is not on the ictideri device appealing and the fre- hand, queiiz of the cycle pulses fed to the counter The object of the invention is to provide a contains changing device. 60 particularly simple and practically usable egg 3, control device according to claim 1, thereby indicating the direction that the signals of the traffic * characterized) that the register (35) also ämpelatilagen in a larger area, which is in flee cycle pulses (Cl, C2, C3) and is divided as a rerc areas, so coordinated controls, second counter with the same counting capacity as that in and between these areas an equal first counter (15) is designed and a moderate flow of traffic is guaranteed, grial (OS) when there is a predetermined starting from a control device of a " Has reached the payment status, and that the circuit type mentioned, this task is according to the arrangement solved the difference between the invention in that all Bereidissteuer-