NO750900L - - Google Patents

Description

The invention relates to a transmission system for an information signal via a recording medium, which information signal is recorded in a first channel on the recording medium.

During recording of signals on a recording medium such as e.g. recording of audio signals on magnetic tape, the signals can be distorted as a result of non-linear transmission characteristics of the recording equipment and the recording medium and noise introduced e.g. of the magnetic tape and which can greatly change the signal's signal-to-noise ratio.

Various circuits and systems are known in and of themselves to improve the signal-to-noise ratio and/or reduce the effect of the distortion. Such circles include i.a. dynamic noise limiters that reduce the effect of noise appearing on the magnetic tape by exfcra amplification of relatively weak signals and/or signal components during the recording and return to the original level during reproduction.

Such well-known circles have, among other things, the disadvantage that the original signal is subjected to processing that causes distortion and that precautions are taken in advance, so that it is not possible to take recording disturbances such as noise, distortion and lack of signal into consideration, even if the effect of these disturbances is reduced. The purpose of the invention is to provide a transmission system where the effect of these disturbances such as e.g. band noise is suppressed to a significant extent.

This is achieved according to the invention by recording a compensating signal in a second channel on the recording medium which is in relation to noise and distortion components which are supplied to the information signal in the first channel as a result of unsatisfactory transmission characteristics.

Further features of the invention will appear from claims 2-17.

The invention will be explained in more detail below with reference to the drawings. Fig. 1 shows in block diagram a first embodiment of a transmission system according to the invention. Fig. 1a shows a block diagram of a recording apparatus

for use in the transmission system according to the invention.

Fig. 1b and 1c show block diagrams for two exemplary embodiments of reproduction apparatus for use in the transmission system according to the invention. Fig. 2 shows in the block diagram a second embodiment of

the transmission system according to the invention.

Fig. 2a shows a block diagram for a recording device for use in a transmission system according to the invention. Fig. 2b 6<*>g 2c show block diagrams for two embodiments of a reproduction apparatus for use in a transmission system according to the invention. Fig. 3 shows a block diagram for a first embodiment of an apparatus for recording and reproduction in a transmission system according to the invention. Fig. k shows a block diagram for a second embodiment of a combined recording and reproduction apparatus for use in a transmission system according to the invention.

It should be noted that components in the drawing which have the same function and characteristics are provided with the same references.

Fig. 1a shows a recording apparatus for signals on a recording medium, e.g. a magnetic tape. The signal input terminal 4 is connected to the input 5 of a time delay circuit T and to a first converter 1, e.g. a magnetic head which records signals supplied to the converter in a first recording channel S^. Exit 6

from the time delay circuit T is connected to a first input 8

in a comparison device A. The second input 7 in the comparison device A is connected to a second converter 2 which

reads a signal which is recorded in the recording channel and which is located at a distance 1 from the converter 1. The output 9 of the comparison device A is connected to the input 10 of an amplifier B whose output 11 is connected to a third converter 3 which records the supplied signal in a second recording channel S^ . and as be-

is at the same level as converter 2 for the recording channel Sj.

It is clear that in a practical embodiment the comparison device A and the amplifier B can be combined into a single differential amplifier. Furthermore, it should be noted that the way in which the signals are recorded in the tracks, e.g. the modulation method, is not of importance for the systems according to the invention. Fig. 1b shows a reproducing apparatus for signals which are recorded using the apparatus in fig. la._ The converter 2 is here connected to a first input in a summing circuit C via a for stronger B. The converter 3 reproduces the signal^ in the channel .S^ and is connected to a second input 13 in the summing circuit C. The output 1<*>1 from the summing circuit also forms the output of the reproduction apparatus. Fig, 1c shows a modification of the apparatus of fig. lb and the signal recorded in the first channel is supplied to the first input 12 of the summing circuit via a time delay circuit T and the amplifier B from the first converter. The operation of the device can be best explained by assuming that a signal S(t) is applied to the signal input time This signal is recorded in channel Sl. Thereby, a disturbed signal will appear which consists of distortion, noise etc. This signal is denoted N(t). A signal S(t) + N(t) is recorded in the channel Sl. This signal is reproduced by converter 2 after a time delay

t = l/v, where v is the speed at which the recording medium is moved in relation to converters 1,2 and 3. The signal reproduced by converter 2 is proportional to S(t}~ t) + N(t - t ). If the gain between the signal input ^ and the input 8 in the comparison device A is not equal to the gain between the signal input 4 and the input 7 in the comparison device A, this must be compensated for e.g. in the comparison device A. Furthermore, it is necessary, for example by means of filtering, to ensure that the signal at the input 8 of the comparison circuit A does not contain any components that are not located or with sufficient strength are not located in the part of the signal reproduced by the converter 2, because these components can contribute much more to the output signal from the comparison device than the disturbance signal N(t). Under these conditions and if the time delay x for the time delay circuit is equal to T = l/v, the output signal from the comparison device A will be proportional to the disturbance signal

-N(T - t). The output signal from the comparison device A is amplified in the amplifier B and recorded in the channel S2 by means of

the converter 3. The amplification of the signal -N(t- x) is necessary

because this csignal is of the same order of magnitude as the recording disturbances in the case of recording in the channel S2.

During reproduction, the reproduced signal -N(t - x) from the channel S2 is summed to the signal S(t - x) + N(t -x ), which is amplified by the amplifier B and reproduced from the channel Sl by means of the converter 2 .Consequently, the output signal on terminal l1* will be practically completely free of the interference signals and is completely identical to the input signal on terminal 4.

As a modification of the apparatus in fig. lb, the mutual setting of the amplitude of the two output signals can take place in one damping circuit which is inserted between the converter 3 and the input 13 of the summing circuit C, while the converter 2 is connected directly to the input 12 of the summing circuit.

Instead of reproducing the signal in the channel Sl using the converter 2, this can e.g. happen with the help of the converter 1 as shown in fig. lc. The signal is then subjected to an additional delay

x e.g. using a time delay circuit T between the inverter

1 and the input 12 in the summing circuit C.

Since the signal supplied to the converter 3 during recording (fig. 1a) can be relatively much stronger than the signal reproduced by the converter 2, the circuit can start to oscillate as a result of cross-talk between the close-to-one converters 2 and 3. increasing distance between the converters is in reality no real solution to this problem when it is desirable to use the area of the record carrier as efficiently as possible. Several methods are known for electronic cross-talk suppression. Application of a fork coupling which. is known from telephone technology - and also recording signals in different frequency bands can be a solution. In the case of magnetic recording, the output signal from the comparison device A can be recorded in the channel S2 in accordance with what is known from Dutch patent application No. 7?$0?.^94 where a low-pass filter is inserted between the converter 2 and the output 7 from the comparison device A.

A non-electronic solution to the crosstalk problem consists in placing a converter 3 side by side with the converter 1 as shown in fig. 2a. During reproduction of the recorded signals, one can 'with the help of converters 1 and 3 as shown in fig. 2b or by means of the converters 2 and 3 as shown in fig. 2c achieve this. In the case of reproduction in accordance with fig. 2b is the time delay circuit T

inserted between the converter 1 and the amplifier B because in the case of drawing according to fig. 2a there is a time difference between the signals in the channels Sl and S2. Under reproduction according to fig. 2c, this time difference is compensated automatically by different placement of converters 2 and 3.

The time delay device T must satisfy strict requirements. When the shift times and l/v deviate by half a wavelength at a certain frequency from an electrical point of view, not only the signal N(t) is obtained at the output of the comparison device A for this frequency, but also a component S(.t) with the double amplitude hoot for this frequency. In order to meet the strict requirements for the time delay device T, there are, among other things, possible to use a small magnetic disk storage device and analog shift registers. This enables the time delay to be varied by means of a time signal in accordance with variations of the speed v with which the converters and the record carrier are moved in relation to each other. Ora it is desirable to compensate for speed variations depending on the requirements and the equipment used. In the case of audio recording on magnetic tape using professional equipment, speed variations can be limited to 0.05?. When the converters 1 and 2 are arranged - at a distance of 1 cm and when the belt speed is 76 cm per second, speed variations of 0.0051 will cause an error of 5/Um. A maximum error only occurs for a signal with a wavelength of 10/Uiii, i.e. at approx. 80 kHz. At lower speeds and in the case of recording equipment for a wider frequency band, it will be necessary to apply band speed correction. One possibility for this is to use a recording medium with a pilot signal to modulate the time frequency of the shift register by means of this or to record the time frequency directly on the recording medium. The time delay t for the shift register is inversely proportional to the time frequency, so that the time frequency must increase with increasing frequency.

If the recording medium contains one pilot signal of a particular wavelength, the frequency is off. the reproduced pilot signal proportional to the speed, so that this signal can be used directly or indirectly as time frequency for the shift register.

The devices in fig. 1 and 2 can be combined into one device for recording and reproduction «red with the help of venders.

Fig. 3 shows an example of a combined recording and reproduction apparatus for use in transmission systems according to the invention, namely based on fig. 1a and fig. lb and therefore have the same references. Via a switch 15 in the position shown with a solid line, the converter 2 is connected to the input 7 of the comparison device A and in the other position, which is shown with solid lines, a switch 17 connects the input 10 of the amplifier B with the converter 2, while the switch 17 in the position with a solid line connects the output 9 of the comparison device A with the input 10. The output 11 of the amplifier B is connected to the converter 3 via the inverter 18 in the position shown with a solid line and a inverter 16 in a position shown with a solid line, while the turner 16 is in the position shown by the dashed line. connects the converter 3 to the input 15. in the summing circuit C whose second input 12 via the inverter 18 in the position shown by the dashed line is connected to the output 11 from the amplifier B. For the recording of signals all the inverters are in the position shown by solid lines and for rendering the venders are in the position shown by dashed lines.

For the devices in fig. 1,2 and 3, it is assumed that the signals are recorded in channels Sl and S2 in two separate tracks on the recording medium. If the recording bandwidth and the reproduction device and/or the recording medium allow this, it is possible to modulate the compensation signal N(t) in a frequency band that deviates from the frequency band of the signal S(t) and record the signals together in one track on the recording medium. In this case, channels Sl and S2 are separate frequency bands. This system has the advantage that the necessary recording area is halved. The above-mentioned method shall be explained in more detail with reference to fig. 4"

The apparatus of fig. 4 comprises only two converters 1 and 2 of which one 1 has two inputs 19 and 20. The input signal supplied to input 20 is recorded in channel Sl, while a signal in a deviant frequency band is supplied to input 19 (channel S2). The apparatus also comprises a time delay device T, a comparison device A, an amplifier B and a summing circuit C with the same reference number as in the previous figures. The signal input terminal M is connected to the input 5 of the time delay device T and the input 20 of the converter 1, while the output of the time delay device T is connected to the input 8 of the comparison device Å. The converter 2 is via a filter P which has a frequency passband corresponding to the frequency band of the channel Sl, and via a switch 15 in the position shown with a solid line connected to the input 7 in the comparison device A and in the position shown with a dashed line and via the switch 17 in the position shown with a dashed line connected to the input 10 in the amplifier B whose output 11 via the inverter 18

in the position shown with a solid line is connected to a first transposition device M fieks. a modulator and in the second position which is shown with broken lines connected to the input 12 of the summing circuit G. The input 13 of the summing device C is connected to the output of a second transposing device D e.g. a demodulator, whose input via a inverter 16 in the position shown with a dashed line is connected to the input 19 in the converter 1, while the output 19 in the converter 1 under drawing acts as an input via the inverter 16 in the position shown with a solid line and connected to the output of the transmission 3 device M. The output 9 of the comparator circuit is connected to the input 10 of the amplifier B via the inverter 17 in the position

which is shown with a solid line.

When all the switches are in the position shown with solid lines, the device is intended for recording signals in the transmission system according to the invention. The output signal from the equalization device is transposed after amplification in the transposition device M to a frequency band corresponding to the channel S2 and supplied to the converter 1. This can, for example, achieved by mixing or modulating a carrier wave. When all the reversers are in the position shown with broken lines, the device is suitable for reproducing signals in the transmission system according to the invention. The signal in the channel Sl is reproduced by the converter 2 and after filtering and amplification it is supplied to the summing circuit C and the signal in the channel S2 is reproduced by the converter 1 and after . transposition in the transposition device D, the signal is supplied to the summing circuit C, so that the original signal is obtained at the output 14.

Although the above description mainly deals with combined apparatus for recording and reproduction, the invention is

of particular interest for use with preset record carriers, e.g. record carriers that are manufactured as a

fully recorded program.- When the system according to the invention is used for such recording carriers, it is of great importance to choose an embodiment where the reproduction apparatus is as simple and cheap as possible, because only this part of the transfer system is

of importance to the buyer. The recording apparatus, which is primarily only necessary for the sam to produce such pre-recorded recording carriers, such as e.g. magnetic tapes used in standard cassettes can be complicated and expensive without this meaning.

When this is taken into account, it is clear that the reproduction apparatus of fig. lb is advantageous when two separate tracks are used because in this device the two reproduction heads have the same tangential position, which is an advantage from a display technology point of view and because no delay device is necessary...

The embodiment in fig. 4 where two separate frequency bands are used as channel Sl. and S2 in a single track, also need no delay device in the reproduction device. The two converters must then have different tangential positions. This can be prevented by taking precautions on the recording side and by not recording an amplified disturbance signal with the converter 1 as shown in fig. 4, but. with the converter 2. The signal recorded at a certain point on the recording medium and the disturbance signal recorded at the same point therefore correspond in time, so that during reproduction only a single converter is sufficient and no delay device is necessary. A problem with this method of recording is that the converter 2 must simultaneously read the signal recorded in the channel Sl and record the disturbance signal in the channel S2, so that the converter must completely fulfill very strict conditions. Strict precautions must also be taken to prevent oscillation because via the converter 2 a loop is formed in which the filter, the comparison device A, the amplifier B and the modulator M are located. In order to solve this latter problem, the Q measured and amplified interference signal (the output from the amplifier) can be recorded using a third converter which is tangentially shifted in relation to the converter 2. The interference signal must then be delayed by a time corresponding to the transfer time from the record carrier via the converter 2 to the third converter, and it requires a second delay device which is applied to the disturbance signal. A disadvantage of this method of recording, however, is that the inevitable relationship between the recorded signal and the recorded interference signal is lost, so that any suppression of the interference signal may have less effect than with the other embodiments described above.

Claims (17)

1. Transmission system for information signal via a recording medium, which information signal is recorded in a first channel on the recording medium, characterized in that in a second channel on the recording medium, a compensation signal is recorded which is in relation to noise and distortion components which are supplied to the information signal in the first channel as a result of unsatisfactory transmission characteristics. 2. Transmission system according to claim 1, characterized in that the compensation signal consists of a signal that is derived from the read information signal that is recorded in the first channel and that is delayed by a time t and compared to a signal that is derived from the original information 3sf: ghal by hjjelp of a for delay device with the same time delay t and amplification of the measured difference signal. 3* Transmission system according to claim 1 or 2, characterized in that the first and second channels consist of two separate tracks on the recording medium. 4. Transmission system according to claim 1 or 2, characterized in that the first and second channels occupy two separate frequency bands in a single track on the recording medium. 5. Transmission system according to one of the preceding claims, characterized in that the information signal and associated compensation signal in time mutually occupy the same tangential positions on the recording medium. 6. Transmission system according to one of claims 1-4, characterized in that the information signal and associated compensation signal in time occupy mutually offset tangential positions on the recording medium. 7. Recording apparatus for use in the transmission system according to claim 2, characterized by an input terminal which is supplied with the information signal, a first converter which cooperates with the first channel on the recording carrier for recording the information signal in the first channel, a comparison device with a first and second input for delivery of a difference signal which is proportional to the difference between the signals on the inputs, a second converter sim co-operates with the first channel on the record carrier for reading the recorded information signal with a time delay r and supplying the read signal to the first input of the comparison device, a delay device foot supply of the information signal to the second input in the comparison device with a time delay t, an amplifier for amplifying the difference signal supplied by the comparison device j and a third converter which cooperates with the second channel on the record carrier f or recording of the signal from amplifier in the second channel of the recording medium as a compensation signal. 8. Apparatus according to claim 7, characterized in that the first and second converter are arranged to cooperate with a first track and the third converter with a second track, which is separated on the recording medium. 9. Apparatus according to claim 8, characterized in that the second and third converters are arranged next to each other with the connection line across the connection line between the first and second converters. 10. Apparatus according to claim 7"characterized in that the first, second and third converters are arranged to cooperate with the same track on the record carrier, that a first transposition circuit is arranged to transpose the compensation signal supplied by the amplifier to a frequency band that is different from the frequency band for the recorded information signal, and that the third converter is connected to one of the other two converters to form a common converter. 11. Reproduction apparatus for use in the transmission system according to claim 1, characterized by a fourth converter which interacts with the first channel on the recording medium, a fifth converter which interacts with the second channel on the recording medium, and a summing circuit for summing the signals that are read, on the fourth and fifth converter with mutually correct amplitude ratio. 12. Apparatus according to claim 11, characterized in that the fourth converter is arranged to cooperate with a first track on the recording medium for reading the information signal, and the fifth converter is arranged to cooperate with a second track on the recording medium for reading the compensation signal. 13. Apparatus according to claim 12, characterized in that the two converters are arranged next to each other across the direction of the two parallel tracks. 14. Apparatus according to claim 11, characterized in that the fourth and fifth converters are arranged to cooperate with the same track on the record carrier, that the fourth converter is connected to the summing circuit via a filter for supplying the information signal, and that the fifth converter via a second transposition circuit for transposing the compensation signal to the frequency band occupied by the information signal, is connected to sum- .mering circle. 15. Apparatus according to claim 11, characterized in that the fourth and fifth converters are combined into a common converter which is connected via a filter to the summing circuit for delivering the information signal to the summing circuit, and that the common converter is also connected to the summing circuit via a second transposition circuit for supplying the information signal. . 16. Recording device according to claim 3> where the recording medium is provided with two parallel separate tracks, characterized in that one track contains the information signal and the other track the compensation signal which, after the adaptation of a mutual amplitude ratio which is suitable for compensating the noise and distortion components in the information signal by summation of this to the information signal. 17. Recording carrier for use in the system according to claim 4, where the information signal is recorded in a track in a specific frequency band, characterized in that in a frequency band outside this frequency band a compensation signal is recorded which is suitable for compensating the noise and distortion components in the information signal and adaptation of the mutual amplitude ratio by summing the compensation signal to the information signal.