DE2059247C3 - Method and arrangement for generating running light effects - Google Patents

Description

bers 140 shown. The output terminal of the clock generator 140 is labeled / 1; it is connected to the corresponding node A in FIG. 2 connected. The clock 140 is an RC pulse generator. which has a PNP transistor 56 and an NPN transistor 53. The collector of the transistor 56 is connected via a collector resistor 57 to the Miniis supply potential. The emitter of the transistor 56 is connected directly to the positive supply potential. The base of the transistor 56 is connected to the collector of the transistor 53 via a resistor 55. The emitter of the transistor 53 is connected to the minus supply potential. The collector of the transistor 56 is connected to the base of the transistor 53 via a feedback resistor 54 and a feedback capacitor 50. A further feedback capacitor 49 can be connected in parallel to the capacitor 50 by means of a switch 58. The base of the transistor 53 can be connected to the positive supply potential via a resistor 51 and a switch 52. The base of the transistor 53 is also connected to a switch 46 via a fixed resistor 48 and a potentiometer 47. When the switch 46 is in its right switch position, the pulse generator 140 is not modulated by acoustic signals, that is, "normal running" is present. In this case, the running speed can be regulated in two stages with the switch 58 and continuously with the potentiometer 47. When the switch 52 is in its right switch position, that is to say is open, the pulse generator 140 is switched off, that is to say there is a "running stop".

The preamplifier 120 receives control signals corresponding to acoustic signals, for example from Loudspeaker connection of a radio or a microphone. Lead the two input connections via a fixed resistor 40 and a potentiometer

41 to a transformer 42, which is used not only for impedance matching, but also the running light switching arrangement should also separate from the equipment in front of it (e.g. radio). The transmitter

42 is mi *, one connection of “a secondary winding connected to the base of a transistor 44 via a base resistor 43. The other connection the secondary winding of the transformer 42 leads to the switch. 46. The emitter of the transistor 44 is also connected to switch 46. The collector of transistor 44 is across a collector resistor 45 connected to the base of transistor 53 of pulse generator 140. The transistor 44 is a PNP transistor.

When the switch 46 is in its left switch position, the pulse generator 14C controlled by the control signals supplied to it.

The in F i g. The embodiment of the program memory 160 shown in FIG. 4 consists of a three-stage binary counter 61, the six control outputs of which are connected to a decoding circuit, which in turn is formed by logic stages 62 to 67. Since there are fixed assignments between the logic stages 62 to 67 and the control outputs of the binary counter 61, the light program must be defined in advance in this embodiment of the program memory (single light, single shadow, double light or Γ..ppelschatten etc.). The output 18 to 23 of each Lüßik stage 62 to 67 is in turn connected to a respective network control part 180 to 186 for an incandescent lamp 200 to 206 . The in Fig. 4, except for the absence of the base resistor 25 for the transistor 26, the network control part shown is practically identical to that in FIG. 2 and therefore does not need to be explained again separately.

Even the one shown in FIG. The pulse generator 140 shown in FIG. 5 and the preamplifier 120 differ only insignificantly from those in FIG. 3 illustrated circuits. The output terminal of the in FIG. The pulse generator 140 shown in FIG. 5 is designated by B and is connected to the corresponding connection point S of the binary counter 61 in FIG. 4 connected. In contrast to FIG. 3 are in the circuit in FIG. 5 the polarities reversed. Transistor 56 is an NPN transistor, transistor 53 is a PNP transistor, and transistor 44 is an NPN transistor. The choice between "normal run" and "acoustic run" can be made with a switch 86. If the switch 86 is in its right switch position, there is an "acoustic run", and if the switch 86 is in its left switch position, it means "normal operation". The pulse sequence frequency can also be regulated in two stages with the switch 58 and continuously with the potentiometer 47.

For this purpose 2 sheets of drawings

Claims (2)

Patent claims: 1. Process for generating running light effects with a large number of light sources that are brightness-controlled according to a specific program, characterized in that the speed of the program sequence is controlled by the intensity of acoustic signals will. 2. Arrangement for performing the method according to claim 1, characterized in that the clock generator (140) controlling the speed of the program sequence is an electronic pulse generator with a controllable pulse repetition frequency According to FIG. 1, a light running effect is to be generated with six light bulbs 200 to 206. The program sequence of the light run effect is stored in a program memory 160. The program store 160 has six outputs, each output being connected to an incandescent lamp 200 to 206 via a line power control section 180 to 186. The running speed of the light running program is determined by a clock generator 140 , which the program: mm- memory 160 controls by, according to a calls up the individual program steps one after the other. According to the invention, the speed the program sequence can be controlled by the intensity of acoustic signals. The acoustic signals are converted into electrical signals in a signal converter 100 (for example a microphone) and fed to the clock generator 140 via a preamplifier "120. In this way, the dynamics of a music - so the piece modulates the clock rate of the clock. This has a visual effect, for example, that in forte parts of the piece of music, a hoho Running speed occurs while with piano-Stei-Ien a slow speed of light can be observed is eighth. At a transition between piano and! forte, and vice versa, a correspondingly "dynamic" change in the speed of light travel occurred. The program memory 160 shown in FIG. 2 consists of six flip-flops 1 to 6, which are connected together as a six-stage ring counter. The clock frequency is fed to the ring counter via connection point A. The one Vc. The supply connection of the Fiipflopsl bis6 is via a ·, common resistor 24 with '.'m minus verscv nus supply potential connected The other supply connections the flip-flops 1 to 5 are over. Resistances? up to 11 with the minus supply potentially connected. In addition, the other supply connections of the flip-flops 1 to 5 can Set buttons 12 to 16 with the plus supply pot tial to be connected. Each flip-flop 1 to 5 can use the set button 12 to 16 assigned to it The invention relates to a method for generating running light effects with a plurality of according to a certain program brightness-controlled light sources. Such methods are known in principle. Running light effects are used for advertising, for example used and often seen in bars, nightclubs and shop windows. Since * method according to the invention differs
differs from the known processes, however, by
that the speed of the program sequence
controlled by the intensity of acoustic signals. This means that, for example, the dynamics of a piece of music are connected to the running speed of 35 supply potential. The other supply of the flip-flop 6, which is illuminated according to a certain program, is directly connected to the N; Can control incandescent lamps (color emitters, fairy lights, etc.). The additionally modulated in this way
Lauflichiuffekt is particularly appealing to the viewer. The invention also relates to an arrangement for
Implementation of the procedure described above,
which consists in the fact that the speed of the
The clock generator controlling the program sequence can be set by an electronic pulse generator with a controllable pulse train, ie the frequency is set by pressing the setting buttons. The ring counter can be programmed up to 16. The clock generator is thus a pulse generator whose pulse repetition frequency can be The program can use a '·' · Delete key 17 through which the acoustic Si deletes the first mentioned supply corresponding control signals can be controlled. connections of the flip-flops 1 to 6 with the Embodiments of the invention are connected to 50 plus supply potential. A signal from hand of the drawings. It shows aisles 18 to 23, each fiipflopsl to 6 is used F i g. I a general block diagram of the arrangement for controlling a mains current control part 180 to voltage for generating acoustically controlled light 186 for a corresponding incandescent lamp 200 to 206. running effects, in FIG. 2 is only the mains power control part 180 for the F i g. 2 shows a circuit diagram of a first embodiment incandescent lamp 200. The mains current control part 180 in the form of the program memory and a mains current has a transistor 26, which is fed by the flip control part for an incandescent lamp, flop 1 via a base resistor 25 control pulses F i g. 3 a circuit diagram of a first embodiment can be supplied. The collector of transistor 26 form of the clock and a preamplifier for the is via a collector resistor 27 with the Plusden acoustic signals corresponding control 60 supply potential connected. The emitter of the signals, transistor 26 controls a triac 28. The triac 28 Fig.4 is a circuit diagram of a second embodiment is in series with the AC network and the Form of the program memory and a mains current incandescent lamp 200. Ia the circuit are also two Control part for an incandescent lamp, fuses 31, 32 are provided. In parallel with the triac F i g. 5 is a circuit diagram of a second embodiment 65 28 is a capacitor 29. One side of the form of the clock generator and a preamplifier for the triacs 28 is also due to the minus vericn control supply potential corresponding to acoustic signals. jnale. In Fig. 3 is an embodiment of the clock