NL1005310C2 - Method of copy-protecting an audio signal. - Google Patents

Description

Method of copy-protecting an audio signal

The invention relates to a method for copy-protecting an audio signal recorded on a sound carrier.

Such methods are known in the art. Reference is made, for example, to DE 3808721, DE 3806413 and DE 3806411. In all these cases, a further signal is added to the audio signal which lies outside the audible range and in fact has no influence on the audio signal itself. This further signal is detected in a copying device and used to block the copying process or to significantly deteriorate the quality of the copy produced. To practice these known methods, it is therefore necessary to build detectors and switching mechanisms in the copiers that respond to the added signal.

Another method developed by the CBS company uses a very narrow band filter to filter out a small part of it during the recording of the audio signal. This part is about 3 kHz at 20 and is therefore not recorded on the sound carrier. A detector is installed in the copier that is adapted to this filtered-out frequency band. If the detector determines that there is no signal in the tape, switching mechanisms are activated that make copying impossible. Here, too, the copier must therefore be provided with a detector and with switching mechanisms controlled by the detector. In addition, the audio signal is deteriorated in quality by the filtering process, especially since the selected frequency range around 3 kHz is one of the most perceptible parts of the audible spectrum for the human ear.

The object of the invention is now to indicate how an audio signal recorded on a sound carrier can be protected against copying, without each copying device having to be provided with additional detectors, switching means or the like for this purpose.

35 This object will suffice by a method of copy-protecting an audio signal recorded on a sound carrier, comprising the following steps: a) during the recording of the audio signal on the audio carrier, adding a disturbing signal within the audible part of the frequency spectrum, b) during the playback of the sound carrier, use a cut-off filter with which the interference signal is filtered out.

The sound carrier therefore contains a composite signal, that is to say the audio signal, which is mixed with an interference signal. During playback of this sound carrier on a normal audio installation, this interference signal will be more audible. In order to make the signal inaudible, according to measure b), a filter must be used to filter out the interference signal. The presence of a false signal does not make it attractive to copy this sound carrier, however, since the signal will also be copied every time.

A preferred embodiment of the method according to the invention is characterized in that the audio signal is a stereo signal, that during step a) the interference signal is added to only one of the channels, and that during step b) the barrier filter only obstructs of the respective channel is applied. Subsequently, because the interference signal is added to only one of the channels, the loss caused by the blocking filter during playback of the sound carrier is considerably smaller than with a mono signal.

In order to further reduce the loss of audio information due to the blocking filter operation, it is preferable that the other channel is fed to a pass filter whose bandwidth is at least approximately equal to that of the cut filter, which pass filter provides an output signal to a mixer stage is fitted behind the blocking filter in the way of one channel.

In order to avoid that copies of the one undisturbed channel are still made, it is preferable that the audio signal is a multichannel signal, for example a stereo signal, that a disturbing signal is added to both channels during step a), and that during step b) a blocking filter is used in the paths of both channels.

It is also possible to reduce the loss of information within the framework of the latter working method. A preferred embodiment of the method is therefore characterized in that - the interference signal in the path of the first channel lies in a first frequency band and the blocking filter in this path is tuned thereto, - the interference signal in the path of the second channel is in a second frequency band, different from the first, - the first channel is supplied to a first pass filter whose pass band corresponds to the second frequency band, 5 - the second channel is supplied to a second pass filter whose passband corresponding to the first frequency band, - in the way of the first channel behind the cutoff filter a first mixing stage is included in which the first channel is mixed with the output signal of the second pass filter, and 10 - in the way of the second channel behind the cutoff filter a two mixer stage included in which the second channel is mixed with the output of the first pass filter.

In practice it has been found to be very effective if the interference signal lies in a frequency range below 500 Hz and preferably below 100 Hz, but in the audible part of the frequency spectrum. The hum that generates such a disturbing signal is perceived as very annoying by the average listener and thus forms a very effective protection against copying. In addition, the use of such low-frequency interference signals has the advantage that, in stereo reproduction, the low-frequency signals are generally not very sensitive to direction. If no mixing stages are added, good and very acceptable sound reproduction can be achieved by increasing the bass portion of the undisturbed channel. If mixing stages are used, a sound quality is realized that will also be very acceptable for 25 more experienced listeners.

The invention will be explained in more detail below with reference to the accompanying figures.

Figure 1 shows a first embodiment of a device according to the invention.

Figure 2 shows a further developed embodiment of a device according to the invention.

Figure 3 shows the preferred embodiment of a device according to the invention.

In Fig. 1, a recording device 10 is schematically shown on the left-hand side. This recording device is supplied with the desired audio signal A via the connection 12, while an interference signal S is supplied via the connection 14. Both signals are mixed together and recorded on a sound carrier, such as, for example, a 10 ° 5310 4 compact disc, a tape recorder tape, a magnetic disk, an optical tape, a semiconductor memory, etc. In the figure, only a compact disc is schematically shown as an example. 16 and a cassette tape 18 are shown. On the right-hand side of figure 1 the required playback equipment is shown very schematically. The signal from the sound carrier 16 or 18 is supplied to a filter 20 with which the interference signal is filtered out. The remaining audio signal is made audible via the amplifier 22, for example by means of the loudspeaker 24.

Figure 1 assumes a false signal with a relatively low frequency, which is why the filter is shown as a low-pass filter. However, the invention is not limited to low-frequency interference signals.

Figure 2 shows a further developed embodiment of a device according to the invention, in particular intended for stereo audio signals. On the left is the mixing stage 30 in which one of the audio channels, for example the right channel R, on the connection 32 is mixed with the interference signal S on the connection 34. The signal from the mixing stage 30 is combined with the left channel L on the connection 33 and recorded on the compact disc 36 or on the tape recorder tape 38.

On the right-hand side, the required display equipment is shown very schematically in Figure 2. The left channel 1 is supplied to an amplifier 40 in order to be reproduced via this amplifier and the speaker 42 coupled thereto. The right channel R first passes through a filter 44 in which the interference signal is filtered out and is then fed to a mixer 46. This mixer further receives a part of the left channel which has first passed a high-pass filter 48. The passband of the filter 48 30 corresponds at least substantially to the barrier band of the filter 44. By extracting information from the left channel L in addition to the information lost by the filter 44, the right channel is in fact at least substantially again completely reconstructed. This reconstructed signal is applied to amplifier 50 to be output through speaker 52.

The left channel L is undistorted with the sound carriers 36 and 38. It may be possible for a copyer to copy this channel separately. To avoid this, a 1005310 5 interference signal can be inserted in both channels. A related embodiment is illustrated in Figure 3. On the left in Figure 3 there is a first mixer 60 in which the left channel on terminal 62 is mixed with a first interference signal S1 on terminal 64. In a further mixer 66, the right channel R on the connector 68 mixed with a second interference signal S2 on the connector 70. The resulting mixing signals are combined and recorded on the compact disc 72 or the tape recorder tape 74.

In this exemplary embodiment, it is assumed that the interference signal S1 lies in a different frequency band than the interference signal S2.

The necessary display equipment is shown schematically on the right-hand side in Figure 3. The combination of left channel L and interference signal S1 is applied to a blocking filter 76 in which the interference signal S1 is filtered out. Likewise, the combination of right channel R and interference signal S2 is applied to a blocking filter 78 in which the interference signal S2 is filtered out. Both the left and right channels therefore lack some of the audio information but those missing parts do not overlap. By now additionally providing information in the mixing stages 80 and 82 from the other channel 20, the two channels are ultimately almost completely restored. For this purpose, a part of the left channel is fed via a pass filter 84 to a mixing stage 80 in which this part is combined with the right channel in order to restore this right channel almost completely again. Likewise, the pass filter 86 is used to restore the left channel in combination with the mixer 82. Finally, the left channel is then output through amplifier 90 and speaker 92 while the right channel is output through amplifier 94 and speaker 96.

10Π5310

Claims (7)

Method for copy-protecting an audio signal recorded on a sound carrier, comprising the following steps: 5 a) during the recording of the audio signal on the sound carrier, adding a disturbing signal within the audible part of the frequency spectrum, b) during the playback of the sound carrier use a blocking filter with which the interference signal is filtered out. 10 Method according to claim 1, characterized in that the audio signal is a stereo signal which is added to only one of the channels during step a), and that during step b) the blocking filter is only in the way of the channel in question is used. 3. A method according to claim 2, characterized in that the other channel is fed to a pass filter whose bandwidth is at least approximately equal to that of the blocking filter, the pass filter providing an output signal to a mixing stage which follows behind the blocking filter in the away from one channel. Method according to claim 1, characterized in that the audio signal is a multichannel signal, for instance a stereo signal, that a disturbing signal is added to both channels during step a), and that in the paths of the two channels a disturbing signal is added during step b). blocking filter is applied. Method according to claim 4, characterized in. 30. that the interference signal is in the way of the first channel in a first frequency band and the blocking filter in this way is tuned thereto, - that the interference signal is in the way of the second channel in a second frequency band, different from the first 35. that the first channel is fed to a first pass filter whose passband corresponds to the second frequency band, - that the second channel is supplied to a second pass filter 1005310 whose passband corresponds to the first frequency band that in the way of the first channel behind the barrier filter a first mixing stage is included in which the first channel is mixed with the output signal of the second pass filter, and that in the way of the second channel behind the barrier filter a second mixing stage is recorded in which the second channel is mixed with the output of the first pass filter. Method according to any one of the preceding claims, characterized in that the interference signal lies in a frequency range below 500 Hz and preferably below 100 Hz. A method according to any one of the preceding claim 1, characterized in that the audio signal is a multi-channel signal, and that the method is used at least two channels. 1005310