DE857818C - Communication system with signals divided into quanta - Google Patents

Description

The invention relates to broadband transmission systems and, more particularly, to improvements on transmission systems with subdivided signals.

In the typical current messaging systems in which a subdivision of the Signal wave is used, it is common to use a constant value for the individual signal quanta, d. H. to use a certain number of levels of signal quanta in order to convert the currently existing one To approximate the amplitude of the signal wave. However, since a wave of news is generally a If the amplitude has a variable amplitude, one can obtain advantages if one considers the value of the individual quanta depends on the current character of the news wave. For example, you can use the Measure the message wave more precisely at the points where its amplitude is small, d. H. more closely approximate, if the value of the individual quanta is made small. On the other hand, if the amplitude of the message wave is large, it can be measured or approximated with sufficient accuracy if one considers the value of each Makes quanta pretty big. Hence, a system using quanta with small values provides if such are needed, and quanta with large values if these are used to measure the signal wave amplitude sufficient. H. a system in which the size of each quant is the amplitude of the message wave is adapted, obviously the possibility of considerable channel capacity, which at the correct

Transmission of the message wave is required to save.

The main object of the present invention is to improve the efficiency of communication systems to improve subdivided signals in that the subdivision according to the requirements at hand of the signal is made variable.

According to the invention, however, it is not necessary for

Implementation of the invention, the subdivision into variable quanta with that disclosed elsewhere Linking technique of subdivision into differential quanta.

With the differential quantum subdivision, the efficiency of the transmission of subdivided Signals increased by the fact that instead of the level itself the changes in the level of successive Signals are transmitted. At the receiver, each of the received differences becomes the corresponding one previous levels added, so that ao reassembled the original signal will. For the sake of simplicity, the term differential is used. This term denotes the ratio the difference in the quantum level at the time between the successive sections. if Differential subdivision of this type is used in connection with the present invention in places where the original signal changes slowly is the change in signal level between successive ones Periods of time are small. It can therefore be measured more precisely with small quanta. on the other hand large quanta will be enough to describe a rapidly changing signal.

In this preferred embodiment, in which the advantages of both the differential and the variable Quantum subdivisions are combined, the input signal passes through a subtracter, goes through a level control loop and then arrives at a subdivision element. The stepped output shaft of the Subdivision element goes through a second level control loop, the effect of which on the amplitude of the first level control loop is reciprocal. At this point the path of the signal splits; a branch goes to one Integrator and then back to the subtracter at the beginning. In the other branch the signal is delayed so that it regulates the level control loop during the following period. The output signal for the The encryption element and the transmission circuit are obtained from the subdivision element. This works in the receiver Signal through a further level control loop, which in the same way from its own output signal is regulated. From there it goes to an integrator, which makes an image of the original signal restores.

Of course, it is according to the invention, the variable subdivision both in systems with even subdivision as well as those with differential subdivision. In the same way is the invention can also be used in the technique of multiple differential subdivision.

The invention will be explained on the basis of the following detailed description of certain exemplary embodiments in conjunction with the enclosed Making drawings easier to understand:

Fig. Ι represents a simple, preferably embodiment of the transmission system with variable Subdivision according to the invention;

Figure 2 shows certain waveforms at various points in the system of Figure 1;

Fig. 3 shows, by way of example, an arrangement of a level control loop used in carrying out the invention Can be used;

Fig. 4 shows another example of an arrangement of a level control circuit c-s, dor in the execution of the Invention can be used.

The arrangement of Figure 1 illustrates the application of the invention to differential subdivision. It will be understood that the present invention can be applied to even subdivision systems as well; but since the main advantages of the invention have become apparent when it is used in connection with the differential division, the preferred embodiment shown in FIG. 1 appears best suited for a brief explanation of the present invention. In the system shown in Fig. 1, an input signal 11, which may consist of speech, music, television signals, etc., reaches the subtraction element 12, where another signal 13 is subtracted from it. In order to simplify the explanation of the method of operation of the invention, it is assumed that the input signal 11 has the successive amplitudes a, b, c, d and e (see FIG. 2) and that the output signal 14 of the subtraction element has the corresponding amplitudes u, v , w, χ and y at corresponding times. The subtracter 12 in accordance with the invention may be any of the numerous circuits known in the art for performing subtractions (ie, taking the difference in the amplitudes of two signals). It can e.g. B. simply be a resistor circuit. In Fig. 2, waveform A shows an example of a typical input signal, while waveform B shows the typical output signal of the subtracter for such an input signal.

The difference signal 14 goes to the level control circuit 16, where a signal 17 with the amplitudes pu, qv, rw, sx and ty is generated. The meaning of the values p, q, r, s, and t will become clear as the remainder of the system is described. The operation of the level control circuit 16 will also be understood later in the description of the system. The output signal 17 of the level control loop arrives at a division and subdivision element i8, as is known in the art of pulse code modulation. This element provides a subdivided signal 19 with the successive amplitudes pu ', qv', rw ', sx', ty '. These signals 19 then reach a second level control loop 21, the mode of operation of which is reciprocal to that of the level control loop 16. As a result, the output signal 22 of this level control loop has the amplitudes u ' _s v', w ', χ and y' at the corresponding times. In FIG. 2 C the output signal 17 of the first level control loop is shown, in FIG. 2 D the output signal 19 of the subdivision element and in FIG. 2E the output signal 22 of the second level control loop is shown. Part of the signal 22 becomes

placed on the integrator 23. The resulting here Signal 13 is then, as described above, from the input signal Subtract π so that a differential signal is obtained. Di? shown in Fig. 1.? Embodiment However, the present invention includes besides Td -m a delay means 24, with its HiIL-a Part of the signal 22 is delayed by an amount which in this embodiment is equal to one Unt-Tt ^ ilungspenode is. The delayed signal 26 is used for the level control crisis ib and 21. Of the P \ fe; -Ireg.-lkras ib works in such a way that

- t χ

etc. = η

is. That is, the] ^: aktorcn p, q, r, s and t, with which the signal 14 is multiplied in the level control loop 16, are inversely proportional to the absolute value of the preceding subdivision. It is obvious that for periods of rest p, q, r, s and t have to assume a minimally -n value, which is to be denoted by m. This means

p, q, r, s and t> tu.

To the greatest possible. To simplify the representation, both m and η are set equal to ι in FIG. 2, ie m = η = ι.

It can readily be seen that the successive amplitudes of the signal ig are represented can through

\ η 1 \ ν J \ w) \ χ. J

In the simple case shown in FIG. 2, where m = η - ■ ι, the amplitudes 19

w '

So each subdivision is proportional to the previous subdivision by a factor is, or divided by a constant factor, in this case one. Since the previous Pieces of differentials of the original input signal 11 are produced as the effect of this Kind of subdivision that a slowly changing signal compares very well with the subdivision period is defined, d. H. its portions are small, while a rapidly changing signal is not as well defined is. A rapidly changing signal requires larger sections rather than more levels for transmission.

If, on the other hand, when considering the amplitude of the differential signal 14, then so it can be seen that the quantum value is a function of the signal amplitude, with small quantum values at small amplitudes and large quantum values arise with large amplitudes.

The mode of operation of the level control loop 21 is, as mentioned above, reciprocal to that of the level control loop 16, so that the output signal 22 of the level control loop 21 approximately forms a "subdivided representation of the differential signal 14 at the subtraction element 12. As already stated above, the signal 22 goes to one Integrator 25, the output signal 13 of which is the successive amplitudes 11 ' , u -f- v', 11 + ν ' + ΐΐ' , χι -f- ν '~ w' -ή- χ ', u' -j- v ' + w ' + λ;' -f- y 'etc. f) The signal 13, which is shown in Fig. 2F, is subtracted in the subtraction element 12 from the original input signal 11 with the amplitudes a, b, c, d, e etc., as above The subtraction element supplies the signal 14 with the amplitudes u, v, w, x, y , etc., so that the following relationships arise:

a - ο = u

b - ■■ - u - ν

c - (u ' -f v') = w

d ■■ - (»'-f- i ¹ ' -f- w ') = χ ^ 5

It emerges easily from this

κ ^ a ^ u '

ν £ ^ /; - u ^. v ' 1,' ^ c - b ^ ic '

γ C \ 3 // / "CO Y ^/

-t —_ Ll L Λ

y ° ^ e - d ° ^ y ' etc.

For the convenience of illustration it is assumed that the signal 14 has zero amplitude before the time corresponding to η. It is therefore perfectly clear that regardless of how the level control loops operate, provided that they are reciprocal, the relationships given last are correct and that signal 14 is a differential signal.

According to what is described here with reference to FIG An embodiment of the invention is the signal 19 prepared for transmission to the receiving station such a differential signal, which is also divided variable-Hch. The scope of the invention includes however, also the use of a double, triple or multiple differential signal or even a straight one divided signal. Since, however, a differential signal is used in the implementation of the invention, in order to regulate the variable subdivision, it is useful to send this differential signal and to take advantage of all the advantages achieved by the differentiation.

Briefly summarized it can be said that the level control loop 16 each message piece with a F "actuator multiplied, which is inversely proportional to the absolute value of the immediately preceding piece is. Then this variably multiplied signal 17 is divided. Then the split signal becomes 19 to the level control circuit 21, which multiplies it by a factor, which is the reciprocal value of the Multiplication factor of the level control loop 16 is. After being delayed by the delay means 24, the signal then reaches the level control loops 16 and 21 to be the multiplication of the immediately following To regulate partial value. In the preferred embodiment described here, the message piece is on which the level control loops act, not the original message wave, but instead the differential signal derived from it.

It is also according to the invention, but not necessary for carrying out the invention, to convert the output signal 19 in an encryption device 25 for which one of the types known in the art of pulse code modulation can be selected.

encrypt and transmit the encrypted signal 27 to a receiving station. In the receiving station, the signal is decrypted in a decryption device 28, for which one of the types known in the art can also be used. The decrypted signal is then fed to a level control loop 31 and then to a delay means 32. These devices work exactly in the same way as the level control circuit 21 and the delay means 24 in the transmitter. The result is a signal 33 which is no longer subdivided in a variable manner, but which is still a differential signal. It is therefore fed to an integrator 34 in order to obtain a signal 36 which is an image of the original input signal 11 . It is clear that there: Signal 29 in the receiver is the same as the signal 19 in the transmitter (shown in Fig. 2D). Likewise, the signal 33 in the receiver is the same as the signal 22 in the transmitter (FIG. 2 E).
With the exception of the level control loops i6, 21 and 31, all the elements mentioned, which are used to carry out the invention, are old and known in the art, although their interconnection in the manner shown is new. The level control loops are obviously nothing more than amplifiers with regulated amplification, the amplification not being dependent on the signal to be amplified, but rather on another signal. While such amplifiers are not new, an example to be used in practicing the invention is shown in FIG. Obviously, the operation of the circuit according to FIG. 3 should consist in that a signal 41 (here designated e _y ), which symbolically is one of the input signals (z. B. 14 and 19 in the transmitter of FIG. 1), which are sent to the various Regulated amplifier or level control circuits are placed, is divided by another signal 42 ( denoted here by e ₂ ), which symbolically represents one of the input signals of the corresponding level control circuit (the absolute value of signal 26, for example), which is also sent to the various regulated Amplifiers are placed.

If it is assumed that the amplifier characteristic μ of the symbolic control amplifier 43 has essentially the phase zero and constant amplitude in the frequency range of interest, then within this frequency band μ is simply a real number. It should also be assumed that the multiplication circuit 44 has a gain with respect to the signal 46 (output signal of the amplifier 43, here denoted by e ³ ) which is given by

ß = k (V ₀ -e _t ),

where k is a constant of the multiplication circuit and V _{0 is} a suitably selected bias voltage 47. A ring modulator, as it is known in electronics, can e.g. B. be carried out so that it works in the manner shown. It is then easy to show that
60

According to the invention, the bias voltage V _{0 can be} equal to ■

μ h

can be made so that e ₃ just becomes equal to.

This is the desired relationship of the divider circuit since e _{2 is} the signal by which the levels in circuits 16 and 21 (in the transmitter of FIG. 1) are regulated. The voltage e ₂ , the input voltage for the gain control, can be chosen to represent the absolute value of the previous differential amplitude, as required in the arrangement of FIG. 1, simply by providing a full wave rectifier 48 to which the signal 26 is applied and which supplies the signal 42 (e ₂ ) which represents the absolute value.

It should be noted that in the embodiment described above, the gain of the loop

μβ - ι - f ^ ke ₂

so that there is a positive feedback factor 1 when e ₂ = 0, and that the amplifier 43 amplifies the signal 41 (^ ₁ ) infinitely. If μ} ιε ₂ becomes negative, μβ is positive and greater than 1. If it were an isolated system, the circle would become unstable under this condition and would tend to run away. However, if the circuit comprises a _go intermediary part is a gesa.mten network which forces the circuit to behave correctly, as in the embodiment of the invention, the arrangement described above, for each value of μ ^ ε ₂ are used. gj

Another arrangement that can be used for reciprocal gain control in accordance with the invention is shown in FIG. This circuit is constructed similarly to the circuit in FIG. 3, except that the bias signal 47 (F ₀ ) is omitted and a transmission circuit 49 with

a transmission characteristic of the multiplication circuit 44 (denoted here by β _λ ) is connected in parallel. It can easily be shown that this is the overall desired relationship. is available. This circuit is somewhat easier to implement in practice than the circuit in FIG. 3, since with this arrangement it is not necessary for the transmission characteristic μ to be phase-free and constant in the frequency band. It is already sufficient if the reciprocal value of μ is approximately maintained in the transmission circuit 49 lying parallel to the multiplication circuit 44.

Going back to the system with variable subdivision itself, it is evident that a Error in signal transmission is carried over to the following dividers. This mistake causes a change in the amplitudes of the reproduced signal, which is dormant until the next Period continues, i.e. until the lower limit of the level control multiplier both in the Sender as well as in the receiver is reached. The operation is in spite of an error in the signal transmission normal, except for the intermittent and non-serious disturbance in the system.

Of course, the ones described above are Changes are only examples of the application of the principle of the invention. Numerous other arrangements can be suggested by those skilled in the art without thereby departing from the spirit and scope of the invention.

Claims (6)

PATENT CLAIMS: 1. Communication system with divided into quanta Signals in which the subdivision changes with the degree of change in signal amplitude so that the number of quanta increases with rapidly increasing signal amplitude and at relatively constant successive instantaneous signal amplitudes, thereby decreasing characterized in that a level control loop multiplies each message piece by a factor which essentially inversely proportional to the absolute value of the immediately preceding piece is, and thus variably multiplied pieces, that provides a means of subdividing the said multiplied pieces derived from these variably subdivided pieces, which are called modulated Code pulses are sent. 2. System according to claim i, characterized in that the signal to be sent to a means is applied to the denomination of the signal and the pieces are applied to a means provided by derives them differential pieces that are dependent on the time of the change in the signal, and that the differential signals are applied to the level control loop. 3. System according to any one of the above claims, characterized in that the means in one are arranged in a closed circuit, to whose input the signal is applied and from whose Exit from the variably subdivided pieces to an encrypting transmission means, wherein the level control loop consists of a first level control loop to which the input signal is applied is, and from a second level control loop, to which the variably subdivided pieces reach, so that each variably subdivided piece is multiplied by a factor that of the The absolute value of the previous piece is dependent, and thus the variable multiplied Pieces are derived, wherein a delay means is connected in the circuit to the changeable multiplied pieces of the second level control loop by the time of a division interval to delay, and wherein the delay means delayed pieces at the first and the second Level control loop supplies. 4. System according to any one of the above claims, characterized in that each level control loop is a variable gain amplifier whose gain for each signal piece by the Absolute value of the immediately preceding piece is regulated. 5. System according to claim 3, characterized in that the first level control loop is a variable The amplification circuit is whose amplification for each signal piece is essentially through the reciprocal of the reciprocal of the absolute value of the immediately preceding one Piece is controlled, and that the second level control loop is a variable gain loop, its gain for each signal piece by the absolute value of the immediately preceding one Piece is regulated. 6. System according to any one of the above claims, characterized in that the means are variable subdivided signals transmitted to a receiving station and means in the receiving station restore an image of the signal from the transmitted variably subdivided signals. 1 sheet of drawings 5518 U.