DE20301907U1 - Synthesiser controlled infra red laser security system with 4D barrier and point matrix display - Google Patents

Abstract

the synthesiser has a time base oscillator [1], binary counter [2] and a BCD to decimal converter[3] providing control signals for multiplexing [4]. Counter states are shown on LCD displays [7]. Comparators [5] check states to identify a signal interruption activate information display and triggering of an alarm.

Description

Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel -Kellen, S 02821 / 92635

4D-Safety/rw

Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen

Synthesizer guided IR laser security system with 4P barrier and dot matrix display

- The abbreviation 4D stands for four-dimensional

- The abbreviation IR stands for infrared .

- The abbreviation laser stands for the English expression " light amplification by stimulated emission of radiation ".

- The abbreviation Synthesizers stands for " Synthesized Signal Generator ", here an independent system for generating explicit interrupt bit patterns at the output of the synthesizer.

IR laser light barriers are ideal for securing indoor and outdoor objects in conjunction with an alarm system. They can be installed discreetly with little effort. IR laser light barriers can bridge distances of 100m and more, making them suitable for securing larger buildings and properties. IR laser light barriers work with red visible light, which makes it easier to align the light beam over long distances. A distinction must be made between IR laser light barrier systems with modulated and non-modulated light, whereby the first case is a binary code that is assigned to the carrier light.

I Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, 9 02821 / 92635

-2-

modulated - and only this is accepted by the receiver, which should almost exclude manipulation. Both IR laser light barrier systems have one thing in common: an alarm is triggered immediately if the IR laser light is interrupted or does not reach the receiver. If the well-known IR laser light systems are used to secure borders, a high number of false alarms must be taken into account. The IR laser light systems available on the market have the enormous advantage of being able to bridge large distances, but there are millions of possible interruptions to which an IR laser light system can respond, which is why these systems are only sparsely found in areas of property that need to be monitored, in building surveillance or for internal or external border security.

The object of the invention is to improve the IR laser light barrier systems for securing objects indoors and outdoors, in conjunction with an alarm system, which trigger false alarms due to the millions of possible influences, in terms of reliability and comfort, so that with a 24-channel IR laser wall, for example, the number of possible false alarms can be reduced from 16,777,216 to 23 false alarms - and even to 0 false alarms, and in particular to use the technology so that the interruption of an IR laser beam not only results in a harsh siren noise, but that the system also provides detailed information on the interruption of a laser beam in addition to spatial detection, such as the announcement of the high-resolution breakthrough speed with simultaneous dating and indication of the time and, furthermore, for documentation purposes, image information via a dot matrix display, which provides a good estimate of the spatial dimensions of the breaking body through the IR laser light - Barrier is allowed and stored for documentation purposes, which is achieved with the synthesizer guided IR laser security system with 4P barrier and dot matrix display .

The application of the synthesizer-controlled IR laser security system with 4D barrier and dot matrix display is characterized by its special properties, especially in

• · &ogr; ·

Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, S 02821 / 92635

-3-

position and in comparison with the known IR laser light barrier systems in connection with
an alarm system as a security system. Compared to the well-known IR laser light barriers
- Systems is the synthesizer controlled IR laser security system with 4D barrier and
Dot matrix display with the following advantages:

- Any number of IR laser light barriers are connected in parallel and one above the other to form an IR laser wall, whereby one or more IR laser light interruptions are immediately detected, which are shown on a text display on the one hand and trigger an alarm via a unit integrated with the security system on the other.

- All relevant interruption possibilities are programmed as bit patterns using a mathematical method, connected via AND gate modules, stored as a read-only memory in a synthesizer created for this purpose, and are continuously switched to the Q outputs of the synthesizer via multiplexor circuits when it is put into operation, where these are then checked as synthesized interruption bit patterns in a comparator circuit with the interruption bit patterns coming from the IR laser wall for an interruption of the IR laser wall, which on the one hand immediately leads to an alarm message if the interruption bit pattern of the IR laser light wall is identical to an interruption bit pattern appearing at the Q outputs of the synthesizer in the comparator circuit and on the other hand irrelevant interruption bit patterns are selected out, which limits the number of possible false alarms to an explicit minimum, and the number of possible false alarms can approach zero, and furthermore when Use of an additional IR laser wall also ensures spatial detection of bodies.

- A free-standing IR laser wall can be built with the required security, so that an alarm does not occur if the first IR laser light is interrupted by a grazing hare or small rabbit, whereas an alarm does occur if the first IR laser light is interrupted by a person, as seen from the ground, which can be done via a single

El Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, S 02821 / 92635

The sensor can be installed either via a tubular, weatherproof rubber hose filled with frost-proof liquid as a tube sensor, which is installed along the IR laser wall just above in the ground for this purpose and switches the tube sensor when there is a pressure load that can only be caused by a person, which immediately triggers an alarm, or via an infrared light interruption sensor, which is installed along the IR laser wall just above in the ground for this purpose, the light of which passes through one end into a weatherproof rubber tube with an inner profile and hits an infrared light receiver inserted in the rubber tube at the other end of the rubber tube, whereby the IR laser light is interrupted by the profile embedded in the rubber tube solely through the load of a person, which immediately triggers an alarm, or alternatively via a sensor installed along the IR laser wall just above in the ground for this purpose, below the IR laser wall. embedded capacitance loop, where a circuit only occurs when a person is present and this then immediately triggers an alarm, or it is achieved by arranging the first two IR laser light barriers in such a way that the first IR laser light barrier, when viewed from the ground, is at a distance from the ground so that if a body attempts to overcome the first IR laser light barrier, the second IR laser light barrier, when viewed from the ground, is also interrupted and an alarm is immediately triggered, whereas the second IR laser light barrier is arranged so high that it is not interrupted if the first IR laser light, when viewed from the ground, is interrupted by a grazing hare.

Each IR laser light barrier of an IR laser wall can be adjusted in terms of its resistance in relation to the penetration detection of bodies in any area from normal walkability at a uniform speed up to several times the speed of sound, which on the one hand makes it possible to walk through at desired locations without reducing the sensitivity of the remaining IR laser light protection devices, which is done via a flip-flop circuit with a programmable time window.

Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, S 02821 / 92635

- An IR laser light barrier wall allows the safe detection and reporting of extremely fast-moving objects at a speed greater than one hundred and twenty times the speed of sound, which on the one hand allows objects that are moving quickly to be detected and on the other hand ensures appropriate spatial protection by a single IR laser wall, which is achieved by setting the sensitivity of the synthesizer's 4D barrier to a sensitivity of, for example, "twenty m/s" or "thousand m/s" via the clock frequency of the programmable time base for a given room width of, for example, ten meters, which in the first case means that the IR laser wall alone can be overcome at a speed greater than seventy-two km/h, which is not possible if only ten meters of path are available, which ensures spatial protection via the 4D barrier.

- The measuring devices arranged in the synthesizer are used to register one or more or all IR laser beam interruptions, whereby on the one hand there is a high-resolution temporal recording of the individual IR laser beam interruption, from which the speed of a body at each interruption point of an IR laser beam is calculated, recorded and optionally displayed centrally with information on the time and date, whereby the control signals required to create a display on an LED matrix line are obtained from the available information regarding the individual IR laser beam interruptions and the dwell time of each IR laser beam interruption for the line structure module, whereby the synchronous display of all LED matrix lines as a dot matrix display allows a good estimate of the spatial dimensions of the body breaking through the IR laser light barrier and is stored for documentation purposes.

This problem is solved with the combinations of features that can be taken from the claims.
Advantageous embodiments emerge from the subclaims and the description.

I Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, S 02821 / 92635

In the following, an embodiment of the invention shown in the drawing is explained; it
show:

Fig. 1 Circuit of the synthesizer

Fig. 2 Flip-flop circuit with programmable time window

Fig. 3 Tube sensor

Fig. 4 Infrared light interruption sensor

Fig. 5 Capacity loop

Fig. 6 Time measurement module

Fig. 7 Line structure module

How it works:

Synthesizer guided IR laser security system with 4P barrier and dot matrix display

Fig.l shows the general structure of the synthesizer - here: a five-channel IR laser wall with programmable quartz time base (1), the binary counter (2), the BCD-to-decimal decoder (3), the multiplexor circuits (4), the comparator circuit (5), the text display/alarm system (6), the seven-segment display (7), a flip-flop circuit with programmable time window (8), the read-only memory (9), the memory module (10), the memory module (11) and a time measuring module (12), whereby the output signals of the infrared light receivers (13) are applied to the terminals I ₁ to I _n of the synthesizer Fig.l , which are influenced by the incoming IR laser beams (14), which in turn emanate from the IR lasers (15), whereby the parallel arrangement one above the other several units each consisting of an IR laser (15) and the associated infrared light receiver (13) is to be understood as an IR laser wall (16).

The sampled DC voltage is fed via the programmable quartz time base (1) to the clock input of the binary counter (2), which uses the signals present at its outputs a, b, c and d to control the inputs a, b, c and d of the BCD-to-decimal decoder (3) in order to generate the control signals for the multiplexor circuits (4) via the outputs of the BCD-to-decimal decoder (3).

1 Rüdiger Wintjens, Briener Strasse 148, D - 47 533 Klevel - Kellen, 9 02821 / 92635

and on the other hand to control the terminals xl, x2, x3 and x4 of the text display/alarm system (6), which, in the event of one or more interruptions of the IR laser wall (16), immediately indicates which of the IR laser beams (14) are interrupted.

The output signals of the BCD-to-decimal decoder (3) are used to control the inputs of the seven-segment display unit (7) for the direct display of the counter reading as well as the inputs of the multiplexor circuits (4), whereby all multiplexor circuits (4) form the read-only memory (9) in which all relevant interruption options are programmed in a connection-protected manner according to a mathematical method using AND gates and are anchored in a zero-voltage-protected manner and appear as interruption bit patterns in a counter-reading-dependent sequence at the terminals Ql, Q2, Q3, Q4 and Q _n of the multiplexor circuits (4), which are applied to the terminals El, E2, E3, E4 and E _n of the comparator circuit (5).

In the event of an interruption of the TR laser wall (16), one or more TR laser beams (14) coming from the IR laser (15) are interrupted and do not reach the infrared light receiver (13), while other IR laser beams (14) reach their target, the infrared light receiver (13), unhindered.

Depending on which IR laser beams (14) are interrupted or not, a corresponding interruption bit pattern is present in the comparator circuit (5) at the terminals Fl, F2, F3, F4 and F _n .

In order for the comparator circuit (5) to be able to correctly evaluate the interrupt bit pattern present at its terminals Fl, F2, F3, F4 and F _n , synthetically generated interrupt bit patterns are fed to the comparator circuit (5) via the multiplexor circuits (4) at the terminals El, E2, E3, E4 and E _n , whereby a high level is immediately set at terminal A of the comparator circuit (5) if the actually prevailing interrupt bit pattern coming from the IR laser wall (16) or the interrupt bit pattern present at the terminals Fl, F2, F3, F4 and F _n is identical to an interrupt bit pattern present from the multiplexor circuits (4) at the terminals El, E2, E3, E4 and E _n .

I Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, S 02821 / 92635

-8th-

The high level at terminal A of the comparator circuit (5) immediately clocks the memory module (10), which then uses the signal appearing at its terminal Q to control the text display/alarm system module (6) and trigger an alarm, and also stops the binary counter (2) via terminal Y of the binary counter (2), after which the current interruptions of the IR laser beams (14) are displayed on the text display/alarm system module (6).

Via terminal A of the synthesizer Fig.l, either the signal from the tube sensor Fig.3, the signal from the infrared light interruption sensor Fig.4, or the signal from the capacitance loop Fig.5 is fed directly to the clock input of the memory module (11), via whose terminal Q the text display/alarm system (6) is activated and an alarm is triggered, and furthermore the terminal X of the binary counter (2) is supplied with it and the binary counter (2) is reset, the signals applied to terminals a, b, c and d of which are supplied to terminals xl, x2, x3 and x4 of the text display/alarm system (6), and a separate message is displayed in the text display of the text display/alarm system (6).

The control signals coming from the time measuring module (12) present at the terminals y, ζ and w of the synthesizer Fig.l control the terminals Y, Z and W of the line structure module Fig.7.
To realize a complete dot matrix display, each time measuring module (12) must be assigned a line structure module Fig.7.

A further advantageous embodiment is provided by the flip-flop circuit with programmable time window (8), which is shown in detail in Fig.2 , because it opens up an extension when used simply via a signal input, optionally Il to I _n of the synthesizer Fig.l , in that the signal from an infrared light receiver (13) applied to one of the terminals Il to I _n can be completely blocked out if the signal does not have a stability greater than the time period programmed on the flip-flop circuit with programmable time window (8), whereby according to

• t t

• t ff

! Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, S 02821 / 92635

-9-

Short-term or long-term interruptions of an IR laser beam (14) cannot trigger an alarm.

This is achieved by simply using the flip-flop circuit with programmable time window (8), which is connected, for example, as shown in Fig.l between the terminals Il of the synthesizer Fig.l and the terminal Fl of the comparator circuit (5).

After a mitigation pulse has been emitted by the RC combination (27) during commissioning and the circuit of the flip-flop with programmable time window (8) is in an orderly initial situation, when the IR laser beam (14) is interrupted, the infrared light receiver (13) has a low signal on its output side at its terminal a, which, after inversion by the inverter stage (17), supplies the terminal b of the AND gate (18) with a 1 signal.

Now the pulses coming from the square wave oscillator (19) can reach the terminal &khgr; of the AND gate (18) via the terminal c of the AND gate (18) and be present at the terminal a of the divider circuit (20), whereby a 1 signal only appears at the terminal &khgr; of the multiplexor circuit (21) if the temporal stability of the low signal at terminal a from the infrared light receiver (13) is greater than the product of the period duration tosz (19) and the divider ratio selected with the digital electronic coding switch (22) via the terminals Ql to _Qn of the divider circuit (20).

The 1-signal appearing at terminal &khgr; of the multiplexor circuit (21) clocks the flip-flop (23) and the 1-signal appearing at terminal Q of the flip-flop (23) is fed via terminal &zgr; to one of the terminals Fl to F _n of the comparator circuit (5).

However, if the output signal of the infrared light receiver (13) changes prematurely at its terminal a from low level to high level, the terminal b of the NAND gate (24) is subjected to a high level, whereupon a 1-signal is then set at the terminal &khgr; of the NAND gate (24), whereby the terminal a of the monoflop (25) is triggered with a positively rising trigger pulse, and the output pulse appearing at the terminal b of the monoflop (25) is applied to the terminal b of the AND gate (26), whereupon the output pulse appearing at the terminal &khgr; of the AND

• » · ·· • * • * ·
·· •

] Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, S 02821 / 92635

-10-

Gate (26) appearing O-signal the registers in the divider circuit (20) with respect to
of the counter reading to zero, and the flip-flop circuit with programmable time window
Fig.2 is back in an orderly starting situation.

A further advantageous embodiment is provided by the tube sensor Fig.3 , which is a weatherproof rubber hose (29) filled with a frost-proof liquid (28), at one end of which a programmable pressure sensor (30) is provided, which can be programmed so that the tube sensor Fig.3 does not switch when there is a pressure load, for example from several hares sitting on the pressure sensor Fig.3 , whereas when there is a pressure load from a human body, the pressure sensor (30) immediately switches, which results in the alarm system being triggered immediately.

A further advantageous embodiment is provided by the infrared light interruption sensor Fig.4 , which is an IR laser (15) whose IR laser beam (14) passes through one end into a weatherproof rubber tube (32) provided with an inner profile (31) and at the other end of the rubber tube (32) hits an infrared light receiver (13) inserted in the rubber tube, wherein the IR laser beam (14) is interrupted by the inner profile (31) embedded in the rubber tube simply by the load on the rubber tube (32) by a person, which immediately triggers an alarm.

A further advantageous embodiment is provided by the capacitance loop Fig.5, whereby the increasing capacitance formation by a person leads to a switching of the Schmitt trigger circuit (33), whereby an alarm is immediately triggered.

&Igr; Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, S 02821 / 92635

A further advantageous embodiment is provided by the time measuring module Fig.6 , wherein the entire circuit is automatically placed in an orderly initial situation upon commissioning via the RC combination (34), whereby all memory modules (37), (38) and (39) are correctly set or reset.

The release button (40) is used to clock the memory module (37) with a bounce-free pulse from terminal Q of the RS flip-flop (41), which on the one hand turns off the optical display (42) and on the other hand supplies a 1-signal to terminal b of the AND gate (43), terminal b of the AND gate (44), terminal b of the AND gate (45) and terminal b of the OR gate (46).
This leads to a change in the logic level in the measuring circuit in such a way that a 1-signal is generated at terminal R* of the counter module (47) and the counter module (47) is able to receive incoming pulses via its clock input and the memory module (39) at its clock input terminal &khgr; a 1-signal is present, so that at the moment the IR laser beam (14) is interrupted, an O-signal is present at terminal xl - Fig.l or at terminal xl time measuring module Fig.6 , with which terminal xl is acted upon by the inverter (48) and terminal a of the AND gate (43) is controlled with a 1-signal, whereupon a 1-signal appears at terminal y of the AND gate (43), and on the one hand terminal a is acted upon by the AND gate (44) and with the 1-signal appearing at its terminal y clocks the clock input of the memory module (38), which then sends the O-signal present at its data input to its Q output.

And on the other hand, the terminal a of the AND gate (49) is supplied with a 1-signal, whereupon the 1-signal appearing at terminal y of the AND gate (49)

1. terminal b of the AND gate (50) is supplied with a 1-signal, whereby the pulses coming from the X-TAL oscillator (51) can flow into the counter module (47) via terminal a of the AND gate (50) and via terminal y of the AND gate (50) and

2. the terminal &khgr; of the inverter (52) is supplied with a 1-signal, whereby a 0-signal is established at terminal y of the AND gate (45), which is also supplied to the terminal &khgr; of the memory module (39) and the latter is prepared so that with the rise of the next positive clock edge at the clock input &khgr; of the memory module (39), the 0-signal present at its data input D is switched to the terminal Q of the memory module (39).

I Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, 8 02821 / 92635

-12-

As soon as the IR laser beam (14) - Fig.l is no longer interrupted, a 1-signal is present at terminal xl of the time measuring module Fig.6 or at terminal xl of the inverter (48), whereby a 0-signal is applied to terminal y of the AND gate (43). This means that terminal a of the AND gate (49) is also supplied with an 0-signal, whereupon an 0-signal is applied to terminal y of the AND gate (49), thus controlling terminal b of the AND gate (50) with an 0-signal, whereby on the one hand no more pulses can reach the counter module (47) from the X-TAL oscillator (51) and on the other hand the terminal &khgr; is also supplied with an O signal by the inverter (52), whereby the AND gate condition of the AND gate (45) is fulfilled and this, with its 1 signal appearing at terminal y, clocks the clock input of the memory module (39) via the terminal &khgr;, and the terminal b of the AND gate (49) is supplied with a remaining low level, whereby with a renewed interruption of the IR laser beam (14) - Fig.l no more pulses can reach the counter module (47).

By pressing the reset button (35) once, the time measuring module Fig.6 is placed in an orderly initial situation, whereby this is done in such a way that when the reset button (35) is pressed, a short O signal is sent to the set and reset inputs of the memory modules (37), (38) and (39) via the equivalence element (36) and the AND gate (52).

On the other hand, the reset can also be done by an initialization pulse via the terminal &khgr; of the time measuring module Fig.6.

A further advantageous embodiment is provided with the line structure module Fig.7, wherein the required initialization signal from the terminal ζ of the synthesizer Fig.l passes through the terminal Z of the line structure module Fig.7, with which the reset input terminal R*l of the programmable divider circuit (54) and the terminal R* 2 of the binary counter (55) are applied, and the entire circuit of the line structure module Fig.7 is in an orderly initial situation.
To ensure that the bidirectional bus register (57) cannot receive any information via the data inputs Dl to D _x in the inactive switching phase, there is a low signal at terminal DE of the bidirectional bus register (57).

Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, &bgr; 02821 / 92635

With the beginning of the measuring cycle of the time measuring module Fig.6, changes of the type take place, so that

a. the signal at terminal W of the line structure module Fig.7 assumes a 1-signal, whereby on the one hand a 1-signal is present at terminal DE of the bidirectional bus register (57) via the switch-off delay element (58) and on the other hand from this point onwards all information present at the data inputs Dl to D _x can be recorded in the register with the rise of the positive clock edge at the clock input of the bidirectional bus register (57), and

b. via terminal Y of the line structure module Fig.7, the pulses coming from terminal y of the time measuring module Fig.6 reach terminal a of the programmable divider circuit (54), whereby the binary counter (55) is clocked with the pulses appearing at terminal b of the programmable divider (54), whereupon

c. the signals of the binary counter (55) present at terminals al to a _x are applied to terminals bl to b _x of the BCD-to-decimal decoder (56), and the signals of the BCD-to-decimal decoder (56) present at terminals el to C _x are applied to data inputs Dl to D _x of the bidirectional bus register (57).

With the completion of the measuring cycle of the time measuring module Fig.6, changes of the type take place, so that

a. no more pulses reach terminal a of the programmable divider (54) via terminal Y of the line structure module Fig.7 and, synchronously, the signal at terminal W of the line structure module Fig.7 carries a 0 signal, which means

b. at the output of the inverter (59) a positive clock edge is set at the clock input of the bidirectional bus register (57), whereby the binary information present at the data inputs Dl to D _x of the bidirectional bus register (57) is recorded in the register of the bidirectional bus register (57) and forwarded to its output terminals Al to A _x , and

c. only then are the terminals Ll to L _x of the LED matrix row (60) controlled with the binary information present at the terminals Al to A _x of the bidirectional bus register (57)

I Rüdiger Wintjens, Briener Straße 148, D - 47 533 Klevel - Kellen, S 02821 / 92635

and brighten up more or less of the arranged LEDs Ll to L _x according to the information content, whereby

d. immediately after the counter reading is transferred to the bidirectional bus register (57), a 0 signal is present at the output of the switch-off delay element (58) at the terminal DE of the bidirectional bus register (57), whereby the bidirectional bus register (57) is locked.

The current display via the LED matrix line (60) is also maintained when the entire circuit is reset via terminal Z of the line structure module Fig.7, whereby the information stored in the bidirectional bus register (57) is retained until the next measurement with the takeover command at the clock input of the bidirectional bus register (57) reads in the new information.

Claims (5)

1. Synthesizer-controlled IR laser security system with 4D barrier and dot matrix display, for direct detection and simultaneous display of all IR laser light interruptions of an IR laser wall ( 16 ) with high-resolution, metrological time recording of individual IR laser beam interruptions and the parameters acquired thereby for calculating the breakthrough speeds of a body at any point on the IR laser wall ( 16 ) and for adapted sensitization of the breakthrough security of a room to be secured via the IR laser wall ( 16 ) via the frequency change by influencing the programmable quartz time base ( 1 ), with simultaneous acquisition of images at the moment of the interruption of the IR laser wall ( 16 ) and synchronous storage of the images with information on the date and time via the image construction module Fig. 7, with the optional possibility of the walkability of the IR laser wall ( 16 ) by reducing the sensitivity of one or more IR lasers while simultaneously maintaining the highest resistance of the non-attenuated signals via the flip-flop circuit with programmable time window ( 8 ) arranged at the output of the infrared light receiver ( 13 ), which is characterized in that the sampled direct voltage is applied to the clock input of the binary counter ( 2 ) via the programmable quartz time base ( 1 ), which uses the signals present at its outputs a, b, c and d to control the inputs a, b, c and d of the BCD-to-decimal decoder ( 3 ) in order to obtain the control signals for the multiplexor circuits ( 4 ) via the outputs of the BCD-to-decimal decoder ( 3 ) and also to control the terminals x1, x2, x3 and x _n from the text display/alarm system ( 6 ), via which, in the event of one or more interruptions of the IR laser wall ( 16 ), it is immediately indicated which of the IR laser beams ( 14 ) are interrupted and wherein, furthermore, the output signals of the BCD-to-decimal decoder ( 3 ) are used to control the inputs of the seven-segment display unit ( 7 ) for the direct display of the counter reading as well as the inputs of the multiplexor circuits ( 4 ), wherein all multiplexor circuits ( 4 ) form the read-only memory ( 9 ), in which all relevant interruption options are programmed in a connection-protected manner according to a mathematical method using AND gates and appear as interruption bit patterns in a counter reading-dependent sequence at the terminals Q1, Q2, Q3 and Q _n of the multiplexor circuits ( 4 ), with which the terminals E1, E2, E3, E4 and E _n the comparator circuit ( 5 ), wherein in the event of an interruption of the IR laser wall ( 16 ), the current interruption bit pattern is present at the terminals F1, F2, F3, F4 and F _n of the comparator circuit ( 5 ) and it is the task of the comparator circuit ( 5 ) to compare all synthetically generated interruption bit patterns at the terminals E1, E2, E3, E4 and E _n via the multiplexor circuits ( 4 ) with the interruption bit pattern at the terminals F1, F2, F3, F4 and F _n of the comparator circuit ( 5 ) and only then a 1 signal appears at the output A of the comparator circuit ( 5 ) if both interruption bit patterns are identical, wherein with the high level at terminal A of the comparator circuit ( 5 ) the memory module ( 10 ) which then, with the signal appearing at its terminal Q, controls the text display/alarm system assembly ( 6 ) on the one hand and triggers an alarm and, on the other hand, stops the binary counter ( 2 ) via the terminal Y of the binary counter ( 2 ), after which the current interruptions of the IR laser beams ( 14 ) are displayed via the text display/alarm system assembly ( 6 ), whereby the influence on the synthesizer Fig. 1 can also look like this: then, via the terminal A of the synthesizer Fig. 1, either the signal from the tube sensor Fig. 3, the signal from the infrared light interruption sensor Fig. 4 or the signal from the capacitance loop Fig. 5 is sent directly to the clock input of the memory module ( 11 ), via whose terminal Q the text display/alarm system ( 6 ) is activated and an alarm is triggered and furthermore the Terminal X of the binary counter ( 2 ) is thereby applied and this results in a reset of the binary counter ( 2 ) with whose signals applied to terminals a, h, c and d the terminals x1, x2, x3 and x4 of the text display/alarm system ( 6 ) are applied, and a separate message in the text display of the text display/alarm system ( 6 ) appears. 2. Synthesizer-controlled IR laser security system with 4D barrier and dot matrix display according to claim 1, which provides a flip-flop circuit with programmable time window ( 8 ) and is characterized in that the signal applied from an infrared light receiver ( 13 ) to one of the terminals I1 to I _n can be completely blocked out if the signal does not have a duration greater than the time period pre-programmed on the flip-flop circuit with programmable time window ( 8 ), whereby short-term or longer-term interruptions of an IR laser beam ( 14 ) cannot trigger an alarm, which is achieved by simply using the flip-flop circuit with programmable time window ( 8 ) to connect it, for example according to Fig. 1, between the terminals 11 of the synthesizer Fig. 1 and the terminal F1 of the comparator circuit ( 5 ). is, whereby, after an initialization pulse has been emitted from the RC combination ( 27 ) during commissioning and the circuit of the flip-flop with programmable time window ( 8 ) is in an orderly initial situation, when the IR laser beam ( 14 ) is interrupted, the infrared light receiver ( 13 ) has a low signal on its output side at its terminal a, which, after inversion by the inverter stage ( 17 ), applies a 1 signal to terminal b of the AND gate ( 18 ), whereupon pulses coming from the square wave oscillator ( 19) at terminal c of the AND gate (18 ) reach terminal x of the AND gate ( 18 ) and are present at terminal a of the divider circuit ( 20 ), and only then a 1 signal is present at terminal x of the multiplexor circuit ( 21 ). appears when the temporal stability of the low signal at terminal a of the infrared light receiver ( 13 ) is greater than the product of the period duration t _Osz ( 19 ) and the division ratio selected with the digital electronic coding switch ( 22 ) via the terminals Q1 to Q _n of the divider circuit ( 20 ), whereupon the flip-flop ( 23 ) is clocked with the 1 signal appearing at the terminal x of the multiplexor circuit ( 21 ) and on the one hand the 1 signal appearing at the terminal Q of the flip-flop ( 23 ) is fed via the terminal z of the flip-flop circuit with programmable time window Fig. 2 to one of the inputs F1 to F _n of the comparator circuit ( 5 ), whereas with a premature change of the output signal of the infrared light receiver ( 13 ) at its terminal a from the low level to the high level the terminal b of the NAND gate ( 24 ) is also subjected to a high level, whereupon a 1-signal can then be set at the terminal x of the NAND gate ( 24 ), since the condition for the NAND gate ( 24 ) is thereby fulfilled and with the 1-signal present at the terminal Q* of the flip-flop ( 23 ), the terminal a of the NAND gate ( 24 ) is controlled, whereby the terminal a of the monoflop ( 25 ) is triggered with a positively rising trigger pulse, and with the output pulse appearing at the terminal b of the monoflop ( 25 ) the terminal b of the AND gate ( 26 ) is applied, whereupon with the 0-signal appearing at the terminal x of the AND gate ( 26 ) the registers located in the divider circuit ( 20 ) are to be updated with regard to the counter reading. Zero is eliminated and the flip-flop circuit with programmable time window Fig. 2 is again in an ordered initial situation. 3. Synthesizer-controlled IR laser security system with 4D barrier and dot matrix display according to one of claims 1 to 2, which provides a time measuring module ( 12 ) and is characterized in that the entire circuit of the time measuring module ( 12 ) is automatically put into an orderly initial situation when it is put into operation via the RC combination ( 34 ), whereby all memory modules ( 37 ), ( 38 ) and ( 39 ) are correctly set or reset, after which the memory module ( 37 ) is clocked with a bounce-free pulse from terminal Q of the RS flip-flop ( 41 ) via the release button ( 40 ), whereby on the one hand the optical display ( 42 ) goes out and on the other hand the terminal b of the AND gate ( 43 ), the terminal b of the AND gate ( 44 ), the terminal b from the AND gate ( 45 ) and terminal b from the OR gate ( 46 ) are supplied with a 1-signal, which leads to a change in the logic level in the time measuring module ( 12 ) in such a way that a 1-signal is set at terminal R* of the counter module ( 47 ) and the counter module ( 47 ) is able to receive incoming pulses via its clock input and that the memory module ( 39 ) has a 1-signal at its clock input terminal x, so that at the moment the IR laser beam ( 14 ) is interrupted, a 0-signal is applied to terminal x1 of the time measuring module ( 12 ), which is applied to terminal x1 by the inverter ( 48 ) and triggers terminal a of the AND gate ( 43 ) with a 1-signal, whereupon a 1-signal is applied to terminal y of the AND gate ( 43 ) sets a 1-signal, and on the one hand terminal a is applied by the AND gate ( 44 ) and with the 1-signal appearing at its terminal y clocks the clock input of the memory module ( 38 ), which then sends the 0-signal present at its data input to its Q output and on the other hand terminal a is applied by the AND gate ( 49 ) with a 1-signal, whereupon with the 1-signal appearing at terminal y of the AND gate ( 49 ) firstly the terminal b of the AND gate ( 50 ) is applied with a 1-signal, whereby the pulses coming from the X-TAL oscillator ( 51 ) run via terminal a of the AND gate ( 50 ) into the counter module ( 47 ) via terminal y of the AND gate ( 50 ) and secondly, terminal x of the inverter ( 52 ) is supplied with a 1-signal, whereby a 0-signal is set at terminal y of the AND gate ( 45 ), which is also supplied to terminal x of the memory module ( 39 ) and this is prepared so that with the rise of the next positive clock edge at the clock input x of the memory module ( 39 ), the 0-signal present at its data input D is switched to terminal Q of the memory module ( 39 ), whereby at the moment when the IR laser beam ( 14 ) is no longer interrupted, a 1-signal is present at terminal x1 of the time measuring module ( 12 ) or at terminal x1 of the inverter ( 48 ), whereby a 0-signal is set at terminal y of the AND gate ( 43 ) and this has the consequence that terminal a of the AND gate ( 49 ) is supplied with a 0-signal, whereupon a 0-signal is set at terminal y of the AND gate ( 49 ) and thus the terminal b of the AND gate ( 50 ) is controlled with a 0-signal, whereby on the one hand no more pulses can reach the counter module ( 47 ) from the X-TAL oscillator ( 51 ) and on the other hand the terminal x of the inverter ( 52 ) is also supplied with a 0-signal, whereby the AND gate condition of the AND gate ( 45 ) is fulfilled and this clocks the clock input of the memory module ( 39 ) via the terminal x with its 1-signal appearing at terminal y, and the terminal b of the AND gate ( 49 ) is supplied with a remaining low level, whereby a renewed interruption of the IR laser beam ( 14 ) does not result in Pulses can no longer reach the counter module ( 47 ), whereby the time measuring module ( 12 ) can be reset on the one hand by pressing the reset button ( 35 ) once, and this is done in such a way that when the reset button ( 35 ) is operated, a short 0 signal reaches the set and reset inputs of the memory modules ( 37 ), (38) and (39) via the equivalence element ( 36 ) and the AND gate ( 52 ) or, on the other hand , an initialization pulse for resetting the memory modules (37), (38) and (39 ) is sent via terminal x of the time measuring module ( 12 ). 4. Synthesizer-controlled IR laser security system with 4D barrier and dot matrix display according to one of claims 1 to 3, which provides a line structure module Fig. 7 and is characterized in that the required initialization signal from the terminal z of the synthesizer Fig. 1 passes through the terminal Z of the line structure module Fig. 7, with which the reset input terminal R*1 of the programmable divider circuit ( 54 ) and the terminal R*2 of the binary counter ( 55 ) are applied, and the entire circuit of the line structure module Fig. 7 is in an orderly initial situation, wherein in the inactive circuit phase of the bidirectional bus register ( 57 ) no information can be received via the data inputs D1 to D _x of the bidirectional bus register ( 57 ) because there is a low signal at the terminal DE of the Bidirectional bus register ( 57 ), whereby at the beginning of a time measurement via the time measuring module ( 12 ) the signal at terminal W of the line structure module Fig. 7 carries a 1-signal, and on the one hand a 1-signal is present at terminal DE of the bidirectional bus register ( 57 ) via the switch-off delay element ( 58 ) and on the other hand from this point onwards all information present at the data inputs D1 to D _x can be recorded in the register with the rise of the positive clock edge at the clock input of the bidirectional bus register ( 57 ) and via terminal Y of the line structure module Fig. 7 the pulses coming from terminal y of the time measuring module ( 12 ) reach terminal a of the programmable divider circuit ( 54 ), whereby with the pulses appearing at terminal b of the programmable divider ( 54 ) of the Binary counter ( 55 ) is clocked wildly, whereupon the signals of the binary counter ( 55 ) present at the terminals a1 to a _x are applied to the terminals b ₁ to b _x of the BCD-to-decimal decoder ( 56 ) and the signals of the BCD-to-decimal decoder ( 56 ) present at the terminals c1 to eg are applied to the data inputs D1 to D _x of the bidirectional bus register ( 57 ), whereby with the completion of a time measurement via the time measuring module ( 12 ) changes of the type take place, so that no more pulses reach the terminal a of the programmable divider ( 54 ) via the terminal Y of the line structure module Fig. 7 and furthermore synchronously with this the signal at the terminal W of the line structure module Fig. 7 leads to a 0 signal, which at the output of the inverter ( 59 ) a positive clock edge is set at the clock input of the bidirectional bus register ( 57 ), and the binary information present at the data inputs D1 to D _x of the bidirectional bus register ( 57 ) is recorded in the register of the bidirectional bus register ( 57 ) and forwarded to its output terminals A ₁ to A _x , and only then are the terminals L1 to L _x of the LED matrix row ( 60 ) controlled with the binary information prevailing at the terminals A1 to A _x of the bidirectional bus register ( 57 ) and light up more or less of the arranged LEDs L1 to L _x depending on the information content, whereby immediately after the counter reading is transferred to the bidirectional bus register ( 57 ) at the output of the switch-off delay element ( 58 ) a 0 signal is output at the terminal DE of the bidirectional bus register ( 57 ) is present, whereby the bidirectional bus register ( 57 ) is locked, and the current display via the LED matrix row ( 60 ) is maintained until the new information is read in with the takeover command at the clock input of the bidirectional bus register ( 57 ) upon completion of the next measuring cycle of the time measuring module ( 12 ). 5. Synthesizer controlled IR laser security system with 4D barrier according to one of claims 1 to 4, which provides a memory module ( 11 ) and is characterized in that this memory module ( 11 ) A) serves to receive a signal which comes from a tube sensor Fig. 3, whereby the tube sensor Fig. 3 is a weatherproof rubber hose ( 29 ) filled with a frost-proof liquid ( 28 ), at one end of which a programmable pressure sensor ( 30 ) is provided, which can be programmed so that the tube sensor Fig. 3 does not switch when subjected to a pressure load, for example from several hares sitting on the pressure sensor Fig. 3, whereas when subjected to a pressure load from a human body, the pressure sensor ( 30 ) immediately switches, which results in the alarm system being triggered immediately, which is achieved by applying a switching signal from the pressure sensor ( 30 ) to terminal A of the synthesizer Fig. 1 and reaching the clock input of the memory module ( 11 ) and via the resulting signal to the terminal Q of the memory module ( 11 ) activates the text display/alarm system ( 6 ) and an alarm is triggered and furthermore the terminal X of the binary counter ( 2 ) is thereby actuated and this results in a reset of the binary counter ( 2 ), with the signals applied to the terminals a, b, c and d of which the terminals x1, x2, x3 and x4 of the text display/alarm system ( 6 ) are actuated and a separate message is displayed in the text display of the text display/alarm system ( 6 ) or optionally B) serves to receive a signal which comes from an infrared light interruption sensor Fig. 4, whereby the infrared light interruption sensor Fig. 4 is an IR laser ( 15 ) whose IR laser beam ( 14 ) passes through one end into a weatherproof rubber tube ( 32 ) provided with an inner profile ( 31 ) and at the other end of the rubber tube ( 32 ) hits an infrared light receiver ( 13 ) inserted in the rubber tube, whereby the IR laser beam ( 14 ) is interrupted by the inner profile ( 31 ) inserted in the rubber tube solely through the loading of the rubber tube ( 32 ) by a person, which results in an immediate triggering of the alarm system and is achieved by applying the switching signal coming from terminal a Fig. 4 to terminal A of the synthesizer Fig. 1 and directly to the clock input of the memory module ( 11 ) and via its terminal Q the text display/alarm system ( 6 ) is activated and an alarm is triggered and furthermore the terminal X of the binary counter ( 2 ) is thereby applied and this results in a reset of the binary counter ( 2 ), with whose signals applied to the terminals a, b, c and d the terminals x1, x2, x3 and x4 of the text display/alarm system ( 6 ) are applied and a separate message in the text display of the text display/alarm system ( 6 ) occurs or optionally C) serves to receive a signal which comes from a capacitance loop Fig. 5, whereby the Schmitt trigger circuit ( 33 ) is switched due to the increasing capacitance formation by a person, whereby an alarm is immediately triggered, which is achieved by the switching signal coming from terminal a Fig. 5 being applied to terminal A of the synthesizer Fig. 1 and reaching directly to the clock input of the memory module ( 11 ) and via whose terminal Q the text display/alarm system ( 6 ) is activated and an alarm is triggered and furthermore the terminal X of the binary counter ( 2 ) is applied and this results in a reset of the binary counter ( 2 ), with the signals present at terminals a, b, c and d the terminals x1, x2, x3 and x4 of the text display/alarm system ( 6 ) and a separate message appears in the text display of the text display/alarm system ( 6 ).