FR2549990A1 - Device for putting out a subliminal audio message and method for reducing theft from displays in a shop. - Google Patents

Abstract

The invention relates to a device and a method for putting out a subliminal audio message in an area. The device comprises a processing circuit 10 for ambient sound signals intended to receive ambient sound signals picked up by detectors 30 and to produce, at its output 38, a control signal which follows the variations in the ambient sound signals, and a control circuit 12 for a subliminal message which receives via one input 14 a subliminal message signal and a muffling signal originating from a source 48. The power of these two signals is adjusted on the basis of the amplitude of the signal originating from the circuit 10. Field of application: campaign against theft from displays in shops, etc.

Description

 The invention relates to a device and method for producing subliminal sound signals in an area such as a shopping area reserved for customers in a store. The invention relates more particularly to a device and a method in which the amplitude of the subliminal signal is adjusted as a function of the amplitude of the ambient sound signals coming from the shopping area reserved for customers.

 It has been established that subliminal audio signals, that is, signals emitted below the level of conscious awareness of the speaker, can influence the behavior of the speaker to some extent.

US Patents 3,060,795 and 3,278,676 describe examples of previous research on the effects of subliminal visual and auditory stimulation.

In addition, it appears that the aforementioned Patent No. 3,278,676 relates to the use of subliminal audio messages to combat shoplifting by customers of retail stores. Although the device described in the aforementioned patent has not been studied, it seems that it combines a subliminal sound message with background music. However, during periods of low commercial activity and other periods during which the store is exceptionally quiet, the signal consisting of background music must be raised to a level much higher than that of the subliminal signal because, in the case on the contrary, the latter is at a level allowing it to be consciously recognized by a listener. In addition, due to the great difference in amplitude between the background music and the signal of the subliminal message, the effectiveness of the latter is reduced
It also appears that the device described in the aforementioned patent No. 3,278,676 maintains the background music and the subliminal message combined. high enough for music to be heard even when the store is noisy. However, when the level of the ambient sound signal drops, for example during periods of low commercial activity, the ensemble formed by the background music and the subliminal signal remains at the same level and seems excessively loud. therefore simply that the device described in the aforementioned patent No. 3,278,676 does not adjust the amplitude of a subliminal message as a function of the ambient sound signals coming from a given zone.

 There is therefore a need to have a device and a method emitting subliminal sound messages, in a way that solves these and other problems.

 The invention therefore relates to a method and a device for adjusting the amplitude of a subliminal sound message as a function of the amplitude of the ambient sound signals coming from an area to which the subliminal message is to be transmitted. In accordance with one aspect of the invention, a sound signal processing circuit receives signals representing the amplitude of sound signals present in the area, for example a retail area in a store. This processing circuit produces a control signal intended for an amplitude adjustment or control circuit which regulates the amplitude or the power of a subliminal sound signal to be transmitted to the zone. The amplitude of the subliminal sound signal is set to increase when the detected ambient sound signals increase and decrease when these detected ambient sound signals decrease.

 In accordance with a more particular aspect of the invention, a masking or mute signal is produced and transmitted to the area. This mute signal has frequency and amplitude characteristics that cover the subliminal signal or make it imperceptible at the level of conscious recognition of a listener. In the preferred embodiment, the amplitude of this mute signal is also controlled as a function of the detected ambient sound signals so that it follows the amplitude of the signal of the adjusted subliminal message. The mute or mask signal can be combined with the subliminal signal to form a compound signal having an amplitude determined by the control circuit based on the control signal.

 According to a more particular characteristic of the invention, to reduce the distortion of the signal of the subliminal message, the processing circuit produces a control signal which acts on the control circuit so that the latter slowly increases the amplitude of the signal of the sound message. subliminal at a rate lower than the rate of variation of the ambient sound signals when the latter increase in amplitude. In addition, during periods when the ambient sound signals decrease, to reduce the risk of conscious perception of the signal of the subliminal message, the processing circuit produces a control signal which acts on the control circuit so that the latter decreases to a fast-paced amplitude of the subliminal signal.

 The subject of the invention is therefore an improved device and method for transmitting a sub-liminal sound message, and in particular a subliminal sound message having an amplitude which is adjusted as a function of the ambient noise levels in an area in which the message subliminal sound is emitted. The invention also relates to a method and a device which regulate the amplitude of the subliminal sound message at a first rate when the levels of the ambient sound signals increase in said zone, and at another higher rate, when the levels of the signals ambient noise decreases. More particularly, the amplitude of the subliminal sound signal is adjusted to rise at a lower rate than that of the rise in the levels of the ambient sound signals. The invention also aims to produce a subliminal sound message which is constantly maintained below the level of conscious perception, and in particular to produce a subliminal sound message which is maintained below the level of conscious perception of listeners being in an area, and which is adjusted according to ambient sound signals from the area in order to stay close to the level of conscious perception. Another object of the invention is to produce a masking or muffling sound signal of a subliminal sound signal, the masking signal having an amplitude which is adjusted as a function of the ambient noise levels of an area in which the Subliminal sound message must be issued.

 The subject of the invention is also a device and a method of protection against shoplifting by the emission of a subliminal sound message.

The invention will be described in more detail with reference to the accompanying drawings by way of non-limiting examples and in which
Figure 1 is a simplified diagram of the device for transmitting a subliminal sound message according to the invention
Figure 2 is a simplified view of an embodiment of a signal source for a subliminal sound message and a mute signal
Figure 3 is a simplified diagram of another embodiment of a source of a subliminal sound message signal and a mute signal;
FIG. 4 is a simplified diagram of another embodiment of a circuit for processing ambient sound signals; and
FIG. 5 is a detailed diagram of the circuit for processing ambient sound signals and other parts of the circuit shown in FIG. 1.

 We have now discovered that in an environment with constantly varying ambient sound levels, for example in the shopping area of a store, it is desirable to adjust the signal amplitude of a subliminal sound message so that it follows the amplitude of the ambient sound signals. In other words, by increasing the amplitude of the subliminal sound message when the ambient sound levels increase and by decreasing the amplitude of the subliminal signal when the ambient sound levels decrease, the subconscious perception by the listeners is improved. This leads to an increase in the effectiveness of the subliminal message.

 Consequently, the device as shown in FIG. 1 comprises a circuit intended to control the amplitude of a subliminal sound message signal as a function of the level of ambient sounds in an area or room 26, for example the shopping area, reserved for customers, from a store, to which the signal of the subliminal message is transmitted. This circuit includes a circuit 10 for processing ambient sound signals and a control circuit 12. The latter is designed to receive, at an input 14, a subliminal sound message signal, and the processing circuit 10 comprises at least one input 16 intended to receive signals representing the amplitude or the power of the ambient sound signals of the room. .

The processing circuit 10 and the control circuit 12 regulate the amplitude of the signal of the subliminal sound message received at input 14 as a function of the amplitude of the ambient sound signals received at input 16, so as to produce at a output 18 a subliminal sound message signal having an amplitude whose variations follow those of the level of the ambient sound signals of the zone.

 The signal from output 18 is applied to an output circuit, which in the embodiment shown includes an output mixer circuit 20 having an input connected to output 18, a pre-amplifier and amplifier circuit 22 having an input 21 connected to the output of the mixer circuit 20, and a loudspeaker 24 intended to transmit # to the zone 26, the signal of the subliminal sound message whose amplitude is adjusted. The circuit may also include an optional source 28 of ambient sound signals which produce musical signals or other ambient sound signals applied to an input 29 of the output mixer circuit 20. These ambient signals are combined in the mixer circuit 20 with the signal of the subliminal message of controlled amplitude and the combined signal is emitted by the loudspeaker 24 towards the room 26.

 The preferred embodiment of the device also comprises at least one sound sensor, for example a microphone 30 placed in the area 26. The microphone 30 detects ambient sound signals from the area and produces an electrical output signal representing the detected signals. The microphone output signal is applied to the input 16 of the circuit 10 for processing the ambient sound signals.

 The processing circuit 10 includes a sound channel 32 associated with the microphone 30 in order to modify the input 16 to produce at 34 an output signal which follows the variations of the ambient sound signal applied to the input 16, as described below. Preferably, several microphones 30, 30a, 30b, 30c, 30d etc. are designed to detect ambient sound signals at various points in zone 26. For reasons of convenience, these microphones can be placed in the ceiling of the shopping area.

Corresponding sound channels 32a, 32b, 32c, 32d are associated with microphones 3Da, 30b, 30c and 30d and produce output signals 34a, 34b, 34c and 34d in the same way as sound channel 32. A circuit 36 for computing mean calculates the average of the output signals 34 to produce at 38 a control signal which follows the variations in amplitude of the ambient sound signals detected by the microphones in the commercial area 26.

In the embodiment of FIG. 1, each sound channel 32 comprises a pre-amplifier circuit 40 intended to amplify the input signal 16, a rectifier circuit 42 intended to rectify the amplified input signal, and a circuit 44 intended shaping the signal to modify the rectified ambient input sound signal coming from the microphone 30, as described below,
With regard to this signal shaping circuit, it has now been discovered that rapid variations in the amplitude of a subliminal sound signal risk distorting it to such an extent that it can no longer be recognized by perception. Therefore, to reduce this distortion and increase the subconscious awareness of the subliminal signal, the signal shaping circuit adjusts the control signal so as to vary the amplitude of the signal of the subliminal audio message at a rate lower than the rate of rise in ambient sound signals as the amplitude of these ambient signals increases. However, in the case of sudden drops in the level of ambient sound signals, a slow drop in the amplitude of the subliminal message could lead to a conscious perception of this message. This can be extremely annoying in cases where it is desired to keep the existence of the subliminal message secret, therefore the signal shaping circuit adjusts the control signal so as to drop the power of the subliminal sound message at a rate higher when the strength of the ambient sound signals is reduced.

 Therefore, with this embodiment of the signal shaping circuit 44, the control signal appearing at the output 38 of the averaging circuit 36 varies at a first rate when the ambient sound signals increase and at another rate , higher, when the ambient sound signals decrease. In addition, the control circuit 12 reacts to this variable control signal so as to produce, at output 18, a subliminal sound message whose amplitude is adjusted and which rises at a first rate when the ambient sound signals increase. , and which decreases at a second rhythm greater than the first rhythm, when the ambient sound signals decrease. In addition, to avoid any distortion of the subliminal message, the first rhythm is lower than the rate of elevation of the ambient sound signals.

 It has now also been discovered that delays affect a device emitting subliminal audio messages. These delays are mainly due to the time interval required by the ambient sound signals to reach the microphones and to the time required by a subliminal message, of controlled amplitude, to move from the loudspeakers to a listener. Thus, whatever the speed with which the device reduces the amplitude of the subliminal sound message as a function of the declining ambient sound levels, a reduction in the amplitude of the subliminal message lags behind the reduction in power of the ambient sounds. Consequently, a rapid fall in the ambient sound level can temporarily leave the signal of the subliminal message at a level high enough for it to be perceived by a listener.

In some applications, this is extremely annoying.

 For example, if a subliminal device is used to combat shoplifting in a store, customers may be extremely reluctant to visit the store if they consciously perceive a message normally intended to combat it. against shoplifting, and if they therefore realize that such a device is used. Therefore, while a store can save money by reducing shoplifting, these overall benefits may suffer from customers' reluctance to visit a store using such a device. In such applications, it is therefore desirable to constantly maintain the subliminal signal below the conscious perception range of the listeners.

On the other hand, in other applications such as those aimed at losing weight and in which the listeners realize that a subliminal sound message of weight loss is emitted, it is not as critical to constantly maintain the subliminal message at below. levels of conscious perception.

 To solve this problem, the preferred embodiment of the device according to the invention comprises means intended to produce a masking or muffling signal which masks the subliminal sound message and prevents its conscious perception, in particular during the time intervals at during which the power of ambient noise drops rapidly.

 Thus, as illustrated in FIG. 1, the device comprises a source 48 of subliminal message signals and of masking or deactivation signals, which produces the signal of the subliminal sound message applied to the input 14 of the control circuit 12 . The source 48 also includes an element intended to produce a masking or mute signal having amplitude and frequency characteristics which prevent any conscious perception of the subliminal sound message. The mute signal can bypass the control circuit 12 and be applied directly to the zone 26. However, it is preferable that the amplitude of the masking signal is also controlled as a function of the amplitude of the ambient sound signals. when the room becomes very quiet, the deafening signal can be strong enough to be easily perceived and to become annoying. In addition, if the amplitude of the mute signal remains constant while the amplitude of the subliminal signal has dropped as a result of drops in ambient sound levels, the amplitude of the masking or mute signal becomes so large, for example compared to that of the subliminal message, that the subconscious perception of the latter is affected.

 Although an independent circuit for controlling the amplitude of the mute signals may be provided, the latter are preferably combined with the signal of the subliminal sound message and the resulting composite signal is applied to the input 14 of the circuit 12 As shown in FIG. 1, the control circuit 12 can comprise a voltage-controlled amplification circuit 39, intended to adjust the level of the output signal 18 as a function of the level of the input signal 38 of control .

 As shown in FIG. 2, the source 48 of the subliminal message and of the mute signal can comprise means such as a tape recorder intended to read a recording of a compound signal comprising the subliminal sound message and the mute signal.

In another variant illustrated in FIG. 3, the source 48 of subliminal message and mute signal can comprise a voice synthesizer circuit 50 which produces a component constituting the subliminal sound message of the signals composed of the subliminal message and mute. A suitable voice synthesizer circuit 50 may consist of a commercially available "Digitalker" assembly produced by the company National Semiconductor Company. This package includes an eight-bit memory chip n0 MM52116 with a capacity of 16 kilobits and a speech processor chip, designated
SPC. In addition, a mute signal circuit 52 is provided for producing the mute signal. This circuit can take various forms and includes a white noise signal generator circuit, for example an oscillator producing complex noises with a register. internally shifted. A suitable generator is available from the firm Radio Shack under the designation of random event generator chip n0
S 2688 / MD15837. The outputs of the circuit producing the mute signal and of the voice synthesizer circuit are connected to a mixer amplifier circuit 54, available commercially, circuit 54 in which the output signals are combined. The mixer circuit produces at its output the composite sound signal which is applied to the input 14 of the control circuit 12.

 As previously mentioned, the masking or muffling signal has frequency and amplitude components preventing any conscious recognition by a listener of the signal of the subliminal sound message. More particularly, the mute signal has frequency components which overlap the frequency components of the signal of the subliminal sound message. In addition, the amplitude of the mute signal is slightly higher than that of the subliminal sound message signal. In particular, it has now been found that better results are obtained when the amplitude of the mute signal is continuously maintained at a value between approximately 3dB and 15dB above the signal amplitude of the subliminal message - In addition, the best results are obtained when the deactivation signal is approximately SdB greater than the amplitude of the message signal subliminal sound. In other words, with such amplitude relationships between the mute signal and the subliminal sound message signal, a momentary mask is applied to the subliminal message during time intervals such as during rapid drops in ambient noise levels. when the subliminal message otherwise risks becoming supraliminal. In addition, with such relative amplitudes, the deactivation signal constitutes a satisfactory screen for the subliminal message without affecting a satisfactory subconscious perception of the latter. It should be noted that with such relative amplitudes between the mute signal and the subliminal message signal, the mute signal cannot generally prevent the conscious perception of the subliminal signal when the composed subliminal message and the signal muting have a high amplitude compared to the power of ambient sound signals. However, by controlling the amplitude of the composed signal with respect to the ambient sound signals, as described above, this condition is avoided.

 FIG. 4 represents a variant of the processing circuit for ambient sound signals. Components of this circuit analogous to those of the embodiment of FIG. 1 of the processing circuit bear the corresponding numerical references, increased by 200 with respect to the numerical references of FIG. 1. Consequently, these components will not be described in detail. Unlike the embodiment of the processing circuit of Figure 1, the sound channels of the embodiment of Figure 4 do not include the signal shaping circuit. On the other hand, a circuit 236 establishes the average of the output signals of the respective rectifier circuits before the shaping of the signal by a shaping circuit 244, in the manner described above.

 FIG. 5 represents a circuit for processing sound signals with 4 channels. Since all the channels shown are identical, only the upper channel will be described in detail.

 The sound channel comprises a pre-amplifier circuit 40, a rectifier circuit 42 and a signal shaping circuit 44, connected in series. The input 16 of the channel is connected to the microphone 30 (FIG. 1) and the input signal therefore varies according to the variations in the ambient sound signals detected by the microphone. The input 16 and therefore the microphone output signal are applied to the pre-amplifier circuit 40. More particularly, this input signal is applied by a capacitor 58 of 0.1 microfarad and by a resistor 60 for gain adjustment. 1 kilohm at the inversion input of an operational amplifier 62 whose output is connected by a reaction resistor 64 of 1 megohm to the inversion input. The gain of the amplifier 62 is established by the ratio of the resistors 64 and 60 and, in the case of these particular resistors, the gain is adjusted to approximately 1000. In addition, a positive bias voltage V is applied via a 2 megaohm polarization resistor 66 at the direct input or non-inversion input of the amplifier 62. With the components used in the circuit of figure 5, the positive bias voltage is 6 volts and the negative bias voltage is set at 6 volts. A suitable amplifier 62 is constituted by the amplifier part of a Norton LM 3900 quadruple operational amplifier. When connected as described above, the amplifier 62 reverses and amplifies the signal of input 16.

 To convert the signal applied to input 16 into a DC signal, a capacitor 68 of 0.1 microfarad connects the output of amplifier 62 to the inverting input of an amplifier 70 mounted as a rectifier. precision, also performing amplification and inversion. The rectifier circuit 42 delivers an output signal comprising a positive amplified and inverted half-wave form of the input signal.

More particularly, the output of amplifier 70 is connected to the anode of a diode 74, the cathode of which is connected via a reaction resistor 76 of 1 megaohm to the inversion input of the amplifier 70.

Thus, the positive half-periods of the output signal of the amplifier 70 are transmitted by the diode 74 and a resistor 76 to the inverting input of this amplifier 70. On the other hand, the output signals consisting of the negative half-periods of amplifier 70 are stopped by diode 74. However, since the output of amplifier 70 is connected to the cathode of a diode 72 whose anode is connected to the inverting input of amplifier 70, these half-periods of negative direction are transmitted by the diode 72 to the inversion input of the amplifier 70. The output signal from the rectifier 42 is taken from the cathode of the diode 74 and it constitutes a positive representation of the signal of input 16 and therefore of the amplitude of the ambient sound signals detected by the microphone 30. An amplifier suitable for carrying out this rectification can be constituted by the amplifying part of a quadruple operational amplifier of type 324.

 The rectified output signal from the rectifier circuit 42 is applied to the signal shaping circuit 44. In other words, the output signal from the rectifier circuit is applied to a network of resistors and capacitor. This network includes a 10 kilohm resistor 78 mounted between the output of rectifier 42 and the direct input of an operational amplifier 80, a capacitor 88 of 1 microfarad which connects the direct input of amplifier 80 to ground, and a resistor 86 of 100 kilohms mounted in parallel with the capacitor 88.

This network has a charge time constant of approximately 0.01 seconds and a discharge time constant of approximately 0.1 seconds. Amplifier 80 can be constituted by an amplifier part of a quadruple operational amplifier of type 324 and its output is directly linked by a feedback loop to its direct input so that this amplifier behaves like a load circuit. voltage. The output signal from amplifier 80 controls another capacitor resistor network # comprising a resistor 82 of 500 kilohms and a capacitor 90 of 10 microfarads. The time constant of this latter resistance-capacitor network is approximately 5 seconds. In addition, a diode 84 having a switching voltage of approximately 0.7 volts is connected by its anode to the point of contact between the resistance 82 and the capacitor 90 and by its cathode at the direct input of the amplifier 80. The positive terminal 90 is connected by a resistor 92 of 100 kilohms to the output 34 of the sound channel. This output 34 is then connected to the averaging circuit 36, as described below #. '
For the reasons indicated above, the signal shaping circuit 44 operates in the following manner, in order to produce on line 34 an output signal which increases at a first rate when the detected ambient sound signals increase, and which decreases at a rhythm higher than the first rhythm when the detected sound signals decrease. In addition, due to the delays occurring inside the circuit 44 of signal shaping, and due to the charging time of the resistance and capacitor networks, the output signal present on line 34 rises at a rate lower than the rate of rise in ambient noise signals. This slows down the rate of variation of the subliminal sound signal and therefore minimizes the rapid fluctuations in amplitude of this signal and the resulting distortions. In other words, when the amplitude of the ambient sound signals increases, the signal reaching the capacitor 90 also increases. However, due to the relatively long charging time constant of the network comprising the capacitor 90, the latter charges slowly. Therefore, under these conditions, the output signal present on line 34 is a slow rising DC signal. Furthermore, since the voltage applied to the anode of the diode 84 is greater than or equal to the voltage applied to its cathode, the diode 84 is not conductive. On the other hand, during a sudden decrease in the amplitude of the detected ambient sound signals, the signal applied to the input of the operational amplifier 80 decreases rapidly. Consequently, the voltage at the cathode of diode 84 drops below the voltage applied to the anode of this same diode, this drop being sufficient to cause conduction of the diode. While driving, the diode 84 establishes a short circuit between the positive terminal of the capacitor 90 and the ground, via the resistor 86, which causes a rapid discharge of the capacitor 90. Consequently, the output signal present in 34 drops rapidly, at a rate much higher than the rate at which this output signal 34 rises when the amplitude of the ambient sound signals increases. It is obvious that by adjusting the time constants of the networks of resistors and capacitors of the shaping circuit 44, it is possible to adjust as desired the rate of variation of the output signal 34 as a function of variations in the ambient sound signals.

 The sound channel output signals are applied to the averaging circuit 36. More particularly, the resistor 92 and an identical resistor of each of the other sound channels transmit the continuous output signals of these channels to the inverting input of an operational amplifier 94 mounted so as to establish the average of the signals it receives at its inversion input. Amplifier 94 can be an operational amplifier of type 741. The direct input of this amplifier is to ground and a reaction resistor 96 of 25 kilohms connects the output of amplifier 94 to its inverting input. In addition, a 10 kilohm drop resistor 98 links the output of amplifier 94, which produces the control signal 38, to the control circuit 12.

More precisely, with this particular circuit, the control signal 38 is a variable direct current signal.

Resistor 96 is set to a quarter of the value of the input resistors 92 so that the gain of the averaging amplifier 94 is set to 0.25. In the case where a single microphone is used to detect ambient sound signals, the averaging is obviously not carried out.

 Circuit 12 controls the amplitude of the subliminal sound message composed and of the deactivation signal received at its input 14, as a function of the control signal present on line 38 and therefore as a function of variations in ambient sound levels in room 26. More particularly, the control signal present on line 38 is used as gain control for an amplifier 102 forming part of the circuit 39. The amplifier 102 can be an operational amplifier with transfer conductance, of the CA3080A type, mounted as an amplifier voltage controlled. The control signal present on line 38 is applied to 11 IABC control input of amplifier 102. The latter is conventionally controlled as a single power operational amplifier. In addition, the positive reference voltage is applied by the through a voltage divider network, comprising a resistor 106 of 47 kilohm and a resistor 110 of 47 kilohm #, to ground. The 3 volt signal available on this divider is applied to the direct input of amplifier 102. A capacitor 108 of 10 microfarads links this latter input to ground in order to eliminate parasitic alternating current signals at this input. In addition, the signal of the composed subliminal sound message and the deactivation signal are applied to the input 14 of the amplifier circuit 39 with voltage control. In other words, these signals are transmitted via a capacitor 104 of 10 microfarads to the inversion input of amplifier 102. The output of amplifier 102 is connected to a first side of a potentiometer 112 of 10 kilohms, the other side of which is connected to ground via a resistor 110. The output signal from circuit 39 is taken from potentiometer 112 and, as indicated above, it consists of a message signal composed subliminal sound signal and a mute signal whose amplitude is adjusted as a function of the ambient sound signals of zone 26. The potentiometer slider 112 also makes it possible to adjust the amplitude of the composed subliminal sound signal, controlled by voltage, and the mute signal. Consequently, this amplitude can be selectively adjusted so that the component constituted by the mute signal can be perceived more consciously and clearly to indicate that the device is operational.

 The gain-controlled output signal of circuit 39 is applied via a resistor 114 of 100 kilohms to the inversion input of an operational amplifier 116 located inside the output mixer circuit 20. Amplifier 116 can be an operational amplifier of type 741, mounted as a mixer-invertor. Other optional ambient sound signals, for example music, may be applied to the input 29 of the output mixer circuit 20. This input is connected by a coupling capacitor 124 of 10 microfarads., Connected in series with an input resistance 122 of 100 kilohms, to the inversion input of amplifier 116. A reaction resistance of 100 kilohms is also mounted between the output of amplifier 116 and its inverting input. Since all resistors 114, 118 and 122 are equal, the gain of amplifier 116 is set to 1. The output of amplifier 116 is connected by a coupling capacitor 120 of 10 microfarads to the pre-amplifier and amplifier circuit 22 (FIG. 1) and therefore to the loudspeaker 24 arranged in the area 26. In a particular application in the fight against shoplifting, a subliminal audio message designed to encourage honesty is produced.

Such a signal may include the phrase "I am honest, I do not fly". This subliminal sound message is combined with a mute signal consisting of white noise to form a compound signal applied to the input of the control circuit 12. The amplitude of this compound signal is then adjusted by the control circuit 12 as indicated above, as a function of the variations in the amplitude of the ambient sound signals detected in the shopping area of a store. The signal of controlled amplitude is then sent to the shopping area so that the subliminal message is perceived unconsciously by the people in the store. It has now been determined experimentally that, although shoplifting and other thefts are not completely eliminated, significant reductions in these losses have resulted from the implementation of the device according to the invention.

 It goes without saying that many modifications can be made to the device described and shown without departing from the scope of the invention.

Claims (29)

 1. Device emitting a subliminal sound message to an area (26), characterized in that it comprises a circuit (10) for processing ambient sound signals designed to receive an input signal representing ambient sound signals present in said area , this processing circuit comprising means intended to produce an output control signal which continuously follows the variations of the received input signal, and therefore the variations of the ambient sound signals of said zone, and a control circuit (12) subliminal message having a first input (14) adapted to receive a subliminal sound message signal, this control circuit also having a second input (38) connected to the ambient signal processing circuit in order to receive said output control signal, and the control circuit comprising means for continuously adjusting the amplitude of the signal of the subliminal sound message received and for producing a regulated output signal comprising the signal, of which The amplitude is adjusted, from the subliminal sound message, the adjusted output signal being intended to be transmitted to said zone and having an amplitude which varies according to the control signal in order to increase when the amplitude of the ambient sound signals of the zone increases and decreases when the amplitude of the ambient sound signals of the zone decreases:  2. Device according to # claim 1, characterized in that the ambient sound signal processing circuit varies the control signal at a first rate when the amplitude of the ambient sound signals of the zone increases and at a faster rate when The amplitude of the ambient sound signals of the zone decreases, the control circuit comprising means (39) which, in response to the control signal, produce an adjusted signal for output of the subliminal sound message having an amplitude which increases to a first rhythm when the amplitude of the ambient sound signals of the zone increases and which  minue at a second rhythm, faster than the first rhythm, when the amplitude of the ambient sound signals of the zone decreases.  3. Device emitting a subliminal sound message intended for a zone (26), characterized in that it comprises means (10) of sound detection intended to detect ambient sound signals of the zone and to produce an output sound signal representing the power of the detected ambient sound signals, and means (12) having an input (16) connected to the output of the sound detection means for producing a subliminal message output signal having a power which tracks the power of the sound signals ambient detected in the area.  4. Device according to claim 3, characterized in that the last mentioned means comprise a source (48) of subliminal message intended to produce an output signal constituting a subliminal sound message and a circuit (39) of power control having an input connected to the output (38) of the sound detection means and an input (14) connected to the output of the subliminal message source, the power control circuit comprising means for adjusting the power of the message output signal subliminal received as a function of the ambient sound signals received output so as to produce an output signal of subliminal message modi fd which comprises the output signal of the subliminal message received whose power is regulated.  5. Device according to claim 3, characterized in that the last mentioned means comprise means intended to produce an subliminal message output signal at a power which increases in response to an increase in the power of the detected ambient sound signals, this increase occurring at a rate lower than the rate of increase of the detected ambient sound signals.  6. Device according to claim 5, characterized in that the last mentioned means include means intended to produce an output signal of subliminal message having a power which decreases in response to decreases in the power of the detected ambient sound signals, a rate faster than the rate of increase of the output signal of the subliminal message in response to increases in the power of the detected ambient sound signals.  7. Device emitting a subliminal sound message intended for a zone (26), characterized in that it comprises at least a first means (10) of sound detection intended to detect the ambient sound signals in the zone and to produce a sound signal ambient output representing the amplitude of the detected ambient sound signals, a subliminal message source (48) intended to produce an output signal consisting of a subliminal sound message, a control circuit (12) connected to the output (38) sound detection means and the subliminal message source for adjusting the amplitude of the subliminal message output signal to follow the amplitude of the detected ambient sound signals, and a mute signal source (48) intended to produce and combine a deactivation signal having a frequency and amplitude tick such that when the deactivation signal is combined with the output signal constituted by the subliminal message whose the amplitude is adjusted, this deactivation signal makes the output signal of the adjusted subliminal message outside the conscious recognition range.  8. Device according to claim 7, characterized in that the source of the subliminal message comprises means intended to produce an output signal consisting of a repeated subliminal sound message.  9. Device according to claim 7, characterized in that the subliminal message source and the deactivation signal source comprise means intended to produce a compound signal of which a first component consists of the output signal formed by the sound message subliminal and of which another component consists of the deactivation signal, the control circuit comprising means (39) intended to adjust the amplitude of the compound signal so that it follows the amplitude of the detected ambient sound signals.  10. Device according to claim 9, characterized in that it comprises an element (112) for testing the device, making it possible to selectively adjust the amplitude of the compound signal to bring the deactivation signal into the conscious recognition range and thus indicate that the device is working.  11. Device according to claim 7, characterized in that the source of the deafening signal produces a deafening signal having an amplitude which is greater in virion 3dB at 15dB than the amplitude of the output signal constituted by the subliminal message. whose amplitude is regulated.  12-. Device according to claim 11, characterized in that the source of the mute signal produces a mute signal having an amplitude which is approximately 5dB greater than the amplitude of the output signal constituted by the subliminal message whose amplitude is set.  13. Device according to claim 7, characterized in that the source of the deactivation signal comprises a white noise generator.  14. Device according to claim 9, characterized in that the means intended to produce a compound signal comprise a device for reading a sound recording intended to read a recording of the compound signal.  15. Device according to claim 9, characterized in that the means intended to produce a compound signal comprise a voice synthesizer (50) -destiné to produce the component of the subliminal sound signal.  16. Device according to claim 15, characterized in that the means intended to produce a compound signal comprise a generator (52) of white noise intended to produce the component consisting of the deactivation signal, and a mixer circuit (54) intended to combine the output signal from the voice synthesizer and the output signal from the white noise generator so that the output signal from the mixer circuit constitutes the compound signal.  17. Device according to claim 9, characterized in that it comprises an output circuit having at least one sound loudspeaker (24) intended to transmit towards said zone the compound signal whose amplitude is adjusted.  18. Device according to claim 7, characterized in that the control circuit is also connected to the source of the mute signal and comprises means making it possible to adjust the amplitude of the mute signal so that it follows the amplitude of ambient sound signals detected.  19. Device emitting a subliminal sound message intended for a zone (26), characterized in that it comprises at least one means (30) of sound detection intended to detect ambient sound signals in the zone and to produce an output signal ambient sound represents both the amplitude of the detected ambient sound signals, a subliminal message source (48) intended to produce an output signal consisting of a subliminal sound message, a mute signal source (48) intended to produce and combining a mute signal having a frequency characteristic and an amplitude such that, when the mute signal is combined with the output signal constituted by the subliminal message whose amplitude is adjusted, this mute signal makes it external to the range of conscious recognition, the output signal of the subliminal message set, the device also comprising a circuit (10) for processing ambient sound signals, connected to the so rtie of the sound detection means in order to produce a control signal which follows the amplitude variations of the detected ambient sound signals, an amplitude control circuit (12) connected to the source of subliminal message, to the source of the signal d and the processing of the ambient sound signals in order to control the amplitude of the subliminal sound message and the amplitude of the muffling signal as a function of the control signal coming from the ambient sound processing circuit so that the amplitudes of the subliminal sound signal and of the deactivation signal increase and decrease at the same time as the amplitudes of the detected ambient sound signals, the device also comprising an output circuit comprising a loudspeaker (24) intended to transmit the signal to said zone output consisting of the subliminal sound message, the amplitude of which is controlled and the deactivation signal, the amplitude of which is controlled.  20. Device according to claim 19, characterized in that the circuit for processing ambient sound signals comprises a sound channel associated with each detection means.  21. Device according to claim 20, characterized in that it comprises several sound detection means and several sound channels, each sound channel (32) comprising a rectifier circuit (42) having an input connected to the output of the associated detection means sound in order to receive and produce a rectifier output signal representing the amplitude of the ambient sound signals detected by the associated sound detection means, each sound channel also comprising a signal shaping circuit (44) having an input connected to the output of the rectifier circuit to produce a shaped output signal which increases at a first rate in response to increases in the rectified output signal corresponding to increases in the amplitude of the ambient sound signals detected by the associated sound detection means , the shaped output signal decreasing at a second rhythm, faster than the first rhythm, in response to decreases in the sig rectified output channel, corresponding to decreases in the amplitude of the ambient sound signals detected by the associated sound detection means, the device also comprising an averaging circuit (36) having an input connected to the outputs of the setting circuits signal form, to receive the signal formatted output signals and to calculate the average thereof to produce a control signal corresponding to the average of the formatted output signals received.  22. Device according to claim 20, characterized in that it comprises several sound detectors (30) and several sound channels (32), each sound channel comprising a rectifier circuit (42) having an input connected to the output of the associated sound detector in order to receive and produce a rectified output signal representing the amplitude of the ambient sound signals detected by the associated sound detector, the device also comprising an averaging circuit (36) having an input connected to the outputs of the rectifier circuits in order to receiving the rectified output signals and producing an output signal corresponding to the average of the rectified output signals received, the device further comprising a signal shaping circuit (44) having an input connected to the circuit output means calculation ne to produce a formatted output signal which increases at a first rate in response to increases in the output signal d u averaging circuit, corresponding to increases in the amplitude of the ambient sound signals detected, the shaped output signal decreasing at a second rhythm, higher than the first rhythm, in response to decreases in the output signal of the averaging circuit, corresponding to decreases. the amplitude of the ambient sound signals detected.  23. Device according to one of claims 21 and 22, characterized in that the first rhythm is slower than the rate of increase of the detected ambient sound signals.  24. Device according to claim 19, characterized in that the output circuit comprises an element  (20) intended to combine ambient sound signals, for example music, with the subliminal sound signal, the amplitude of which is controlled, before the emission of the latter signal to the zone.  25. Device according to claim 21, characterized in that the control signal comprises a control voltage, the amplitude control circuit comprising an amplifier circuit (39) controlled by voltage.  26. Method for reducing shoplifting in a store area (26) reserved for customers, characterized in that it consists in detecting ambient sound signals coming from the area, in producing a signal consisting of a subliminal sound message tending to prevent shoplifting, to adjust the amplitude of the signal of the subliminal message so that it follows the amplitude of the detected sound signals, and to transmit to said zone the signal consisting of the subliminal message whose amplitude is settled.  27. The method as claimed in claim 26, characterized in that the adjustment of the amplitude consists in raising the amplitude to a first rhythm when the amplitudes of the detected sound signals increase, and in lowering the amplitude at a second rhythm, more faster than the first rhythm, when the amplitudes of the detected sound signals decrease.  28. Method according to one of claims 26 and 27, characterized in that it consists in producing a deactivation signal having amplitude and frequency characteristics such that, when it is combined with the signal of the subliminal sound message, it brings this subliminal message signal below the level of conscious recognition, the process also consisting in adjusting the amplitude of the deactivation signal so that it follows the amplitude of the detected sound signals and in transmitting towards the zone the mute signal whose amplitude is adjusted.  29. The method as claimed in claim 28, characterized in that the production of the subliminal message signal consists in producing a compound signal of which a first component consists of the subliminal sound message signal and of which another component consists of the mute signal, adjusting the amplitude consisting in adjusting the amplitude of the compound signal so that it follows the amplitude of the detected sound signals, and the emission consisting in transmitting to said zone the compound signal whose amplitude is adjusted.