DE1204704B - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

H041

H04n German class: 21 al-32/11

Number: 1204 704

File number: M 50213 VIII a / 21 al

Filing date: September 4, 1961

Opening day: November 11, 1965

Method and device for improving the signal-to-noise ratio in a message signal, preferably for magnetic storage of television signals

Applicant:

Minnesota Mining and Manufacturing Company,

St. Paul, Minn. (V. St. A.) Representative:

Dr.-Ing. E. Sommerfeld and Dr. D. v. Bezold,

Patent Attorneys, Munich 23, Dunantstr. 6th

Named as inventor:

Wayne Royal Johnson,

Los Angeles, Calif. (V. St. A.)

The present invention relates to methods and devices for improving the signal-to-noise ratio in sent and received or recorded and played back at a remote location Message signals that are transmitted or stored 5 predominantly in a certain frequency range of the frequency band occupied by them are superimposed by interfering signals. A preferred field of application of the invention is the magnetic storage of television signals; however, the invention can also be applied to others Types of recording such as photographic, mechanical or electrical processes can be used. It is particularly suitable for recording very broadband signals. 15th

When recording and playing back a to
frequency band descending to frequency zero
it is known to split the frequency band into several sub-frequency bands and, after suitable frequency transformation, to split them into side by side ao
lying traces on a magnetogram carrier
record at the same time. To get the signal-to-noise ratio at
To improve very low frequencies, these will be
The frequency-modulated signal is inverted at low frequencies before the recording of a sun and this is subjected to the treatment by being recorded by the frequency-inverted signal. This procedural or amplitude modulation in a higher ren is to be shifted by the required carrier modulation frequency position. It is in this
Connection also known in a second track
record and use the entire frequency band

Reproduction of the entire frequency band as a result of which the opposite in wireless receivers can be spoken down Frequency divider as in the case of recording that from the transmitted frequency band tion to use which sifted out those sub-areas of the second by filter and Track recorded total frequency band, the depths of an amplitude limitation are subjected in Separates frequencies in the same way as the ratio of interference voltage amplitude of the recording before the residual frequency band with 35 to useful voltage amplitude is larger than in the the areas removed from the first track and the remaining areas. The sifted and limited ones Reshaped low frequencies are reunited frequency ranges after this processing will. This known method has the disadvantage of being reunited with the rest of the signal. A bedass there are several recording tracks or if they are adjacent, however, in systems where application to the transmission of message signals, a high level of fidelity is generally required several transmission channels are required. do not apply mine.

It is also known in the transmission of a method for improving the signal-to-noise ratio

Speech to improve intelligibility by being perceived in sent and in a distant place the higher language genes or recorded and replayed, frequencies increases and after the transmission 45 here mainly in a certain frequency more or less weakens again. range of the occupied frequency band

Furthermore, a method for recording message signals superimposed on interference signals is at Known video signals on magnetic tape, in which which part of the frequency band of the Video signal one above the highest to be over- message signal separated and contracted separately Video frequency horizontal carrier with a 50 is working, preferably for a magnetic one Storage of television signals is small compared to the video frequency band according to the Erin the frequency is modulated and in which the so obtained invention is characterized in that the separated

expensive and naturally requires a relatively wide frequency band.

After all, it is known that atmospheric disturbances

3 4

The range of the frequency band before transmission or delivery becomes insufficient if the general Recording a nonlinear gain with noise level becomes nearly as large as that subject to an exponent smaller than one and the amplitude of the signals to be reproduced. In the is recombined with the rest of the signal and playback, however, the noise signal becomes the same after the reception or playback of the 5 is amplified early with the useful signals. From this it follows Message signal of the frequency range again from itself, that although the general noise level in the remainder Signal separated, a non-linear comparison with the mean value of the amplitudes of the useful gain with one of the exponents mentioned, rezi- signals can be very small, but that in the vicinity Subject to proken exponents and then before the lower limit frequency and the upper limit recovery of the signal again with the rest of the io frequency, where the signals are a very high amplification signal is united. need to adjust the ratio of the useful signal to

The invention is intended to drop sharply on the basis of the preferred noise signal and the disruptive noise area, namely, the magnetic storage signal is therefore applied to the lower and upper band reeds of television signals. border, in the vicinity of which the largest

It is well known that all records available today are required.

Determination method with regard to the frequency band of the It depends on the special nature of each message signals to be saved. The reproducing signal depends on whether the noise signal The lower limit frequency is mostly determined by the increase of higher or lower frequencies or drawing method determined, while the upper two noise signals the greatest difficulty be-cutoff frequency to some extent from the 20 ride. When playing television signals, Apparatus and in particular from the Ge which theoretically a frequency band from the Fresch speed depends on the recording medium. The frequency range from zero to the frequency 4 MHz, Devices can work with a needle scanner, used for periodic transmission of the an optical slit of photographic re-black level signals at the end of each input device or an air gap of a magnetic 25 line and at the end of each partial image (series of lines) head included. When the dimensions of the ab- facilities to reintroduce the common pushbutton or converters in the recording direction into the current component, which the recording of Magnitude of the wavelength of the reproduced - making extremely low frequencies unnecessary. Daden, If the recorded signal comes, it can be used to set up the high-frequency one in the case of television The drawn signal is no longer flawlessly reproduced are given and finally disappears completely - this is the reason why the present invention continues. The output signal falls when approximating mainly the improvement of the the ratio of useful signal to noise signal at this absolute cutoff frequency and approximately linearly. the upper end of the frequency band.

With the magnetic storage of signals 35 Of course, the same methods can also be used to determine the lower limit frequency at the lower end of the tape.
The high-frequency components of a television proportional in the gradient of the magnetization of the signal can be divided into two categories. The drawing support is so that at low frequencies the first comprises the high-frequency components which, at zen, the output signal has a correspondingly small amplitude of the scanning of a part of the image field. In order to achieve a faithful reproduction of the signals in which there is a sudden jump in brightness, the signals are used. In this context, one speaks of recording and / or reproduction of a steep front used within the useful signal. These are dimensioned more so that their frequency characteristics steep front are given by a frequency spectrum as complementary to that of the recording system, which theoretically extends into the infinite and reproducing system. If the sensitivity extends and actually up to the upper limit of the magnetic heads, which the signal transmission frequency of the transferred tape reaches and in on the recording medium and the signal which the amplitudes of the individual frequencies would decrease from the recording medium, are inversely proportional to the frequency . Which becomes very low, one has to use high levels of amplification 50 second category of high-frequency components. arises when scanning a part of the image

In all recording and playback devices, a field in which there is a high level of detail,

and with all amplifiers a certain size occurs. This may be the case, for example, when in the

a so-called noise. This can occur from picture a picket fence. In the latter case

Irregularities in the playback medium, from 55 the useful signal can almost entirely consist of high frequencies

consist of dust deposited on its surface or of sequences of great amplitude. In general

other imperfections. The greatest of mine, however, are such image details as that

However, part of this noise arises in the aforementioned picket fence, in front of a background, and

amplify themselves. This amplifier noise contains the high-frequency components have a

the so-called resistance noise, which is caused by the relatively low amplitude of the 60

thermal movement within the resistance - by indistinctly that along with them one

materials. It also contains a noise-to-noise signal, which is higher in the case of useful signals.

appearance that would not interfere with the statistical fluctuations of its amplitude. Also bothers

with the emission of electrons from the incandescent with large areas of almost the same brightness

cathodes of the electron tubes. 65 the noise signal is stronger than in parts of the picture where

Experience has shown that the amount of noise occurs in distinctive image details. In the playback picture of all these sources of noise there is almost uniformly the impression of falling snowflakes the whole frequency band is distributed. The as-called.

5 6

When recording television signals, it is output signals to the signals in the input signal always desirable that the transmission frequency have a relationship which is a multiplicaband as far up as possible. This tion of the input signals of the distortion network applies regardless of whether so-called frequency means with a factor. The instant sample band splitting procedures be used. Also 5 tudes are raised to a power, which is the tape speed reciprocal value of the fractional power in the case of this method The speed is much higher than the tape speed of recording, multiplied by the rezibei the sound recording, and the tape consumption proken value of the proportionality constant, the is very high. Furthermore, in the case of a reduction, the first distortion must have been used. The signals the belt speed with this method the io in the two channels are then to each other Number of channels in which a recording adds up, thus restoring the original one, are increased, and with this, higher cost borrowed signals are complete. With color television and recording and reproducing become more complicated when the so-called mixed heights devices connected. Therefore, even with such, it is added to all color channels during recording Method desirable to each individual channel in Figure 15 are to re-use these mixed heights individually in the best possible way. Finally there would be added. If the mixed highs are only in if the problem occurs with these methods that a channel was recorded, the Si phase position becomes which was recorded in the individual tracks of this channel after playback Pay close attention to signals. their signals are added. Either of these two

The following possibilities can be used to carry out the invention. If an addition is carried out in a measured manner: The signals to be recorded for all channels during the recording are passed through a suitable filter network, a further statistical reduction of the in at least two frequency bands or frequency noise signal takes place, namely by a factor before: areas . One of these frequency ranges VVJ, since there are three channels. However, as the noise-loaded frequency range (since the very high frequencies are characterized by the greatest role and the other than the ratio play) the phase problem in the recombination can be moderately noise-free frequency range. When the signals are shown by the aforementioned further miniaturization of television signals, the so-called modification of the noise signal can again cancel that point of intersection of the filter network. The choice of system depends on the one in which the reproduced signals are to some degree dependent on how the signals are to be used immediately after their reproduction has dropped to half their maximum energy level. ie three decibels lower, although the amount of noise reduction that is

actual separation point is not critical. Which can thereby be achieved depends on both Signals in the noisy area enforce the proportionality factor of the linearly amplified signals a non-linear amplifier in which the 35 ab as well as the reciprocal exponent of the instantaneous amplitude of the output signal per non-linear amplifier when recording and proportional to a fractional power of instant reproduction. Considerations for the device dimensioning borrowed amplitude of the input signal. This results in the use of reinforcements The output signal then depends on signals from a square law and a square law, same amplitude in the relatively noisy 40 But smaller exponents can also be used in the free area via a proportionality factor to- recording and larger exponents in the together, which is the product of a constant and a reproduction, so that one can add one to the other Original amplitude to a fractional power additional reduction of the relative noise is raised. The signals of the noisy loading reached. The high frequency components are After this amplification, the lower frequency components are then again superimposed. the the signals of the remainder of the frequency band usually occur in a maximum amplitude, but not added dierschaltung, and always in this way, with sudden transitions in the signal combined signals are recorded. In one of the sensing of sudden changes in brightness Color television system can generate the signals of the noisy in the picture field and then the greatest amplitude occurs loaded range the so-called mixed 50 on, where the low frequencies have their smallest ampli-highs and can either have all three colors.

component signals or just a single one. The dynamic range of each recording

Color component signal can be added. mediums is limited and usually one will

During playback, they will demand this recording area in this way to utilize the recorded signals from the usual scanning unit as far as possible. In the direction of recording decreased, pre-amplified and preference will therefore be sought whenever possible, wisely also equalizes so that the signals up to the maximum amplitude of the non-linear signal to the upper limit frequency in the same relative practically equal to the maximum amplitude of the same Amplitudes are reproduced, which they make in front of the signal before the non-linear amplification. Record owned. According to this comparison- 60 The maximum range of fluctuation that can occur in a The signals are then transmitted to two channels on TV signal (excluding the sync signals) divided, which must have the same frequency ranges to be recorded, starts from the brightest white like the frequency ranges in the recording. The one up to complete black. The maximum amplitude signals of the noisy area prevail tude of the high frequency signals that are recorded then have to become a non-linear amplifier or a non-65, reproduces this whole range linear network, the properties of which are inverse to and if the signal change is erratic, so will Properties of the amplifier or the network the amplitude of the signals, which is the sum of the are in the process of recording. This means that represents the high frequency components, equal to the Am-

7 8

plitude of the lowest frequency or fundamental frequency of the noise signal, with 14 db above the of the jump. To the dynamic range of the noise signal lies.

Using the recording medium as well as possible, the advantage that comes from dividing the tape the output side of the non-linear amplifier must be converted into a noisy signal and a noise-free one

in the noisy channel can be set to 5 signal and by non-linear amplification only

that when A ₀ equals the maximum of the signal, the noisy signal is reached

which the transition from black to white is also due to the fact that the noisy

Output of the relatively noise-free channel Signal at the top of the low-frequency useful signals

reproduces that the amplitude of a signal occurs in the output and that the non-linear amplifiers

of the non-linear channel, which amplify a change in the total amplitude. this

reproduces the same size, the equation bA ^lln = A ₀ becomes clear in the case in which

is equivalent to. Here b is the constant of proportionality a large area of approximately maximum amplitude

and l / n is the fractional exponent. Likewise, tude, which approaches the black level, must be reduced.

the output side of the non-linear amplifier im is scanned. The amplitude of the overall signal has

Playback device the corresponding relationship then follows the value one. If the entire signal is not-

are as follows: (Vb) A " - A _0. would be amplified linearly and the noise signal

Although these relationships would have a maximum assumed value of 0.01 A ₀ ,

■ enable use of the recording medium and so the amplitude of the overall signal would be between

a maximum ratio of the useful signal to the interference 0.99 A ₀ and 1.01 A ₀ fluctuate. After the square

signal, it is not absolutely necessary that these values are very close to 0.98 and

borrowed to realize these relationships in practice. 1.02. The noise component is thus approximately

The only requirement that must be met doubles instead of being largely diminished,

is that the constant factor in the re-When using the band division method according to

power amplifier the reciprocal of the factor in the invention would be the amplitude fluctuation

the nonlinear recording amplifier have 25 of the black area signal due to the noise

must, and that the exponents of the amplitudes are ± 0.0001 A ₀ , ie there would be a difference

functions must also be reciprocal. occur in the noise signal of 48 db.

If the conditions for the maximum out One of the advantages of the invention that maybe

use of the dynamic range is not immediately noticeable, is that through

and the maximum signal amplitude to one assumes the amplitude of the triggered

men, the constants b and Vb are also greatly reduced. Such suitable

if one and can in the subsequent consider- able vibrations can be of a sharp one

tion should be disregarded. As stated above, the drop in the characteristic curve of the equalization

The playback amplifiers are the primary engine that produce the behavior

Source of the noise signal and therefore intended for the 35 at high frequencies near the cutoff frequency

subsequent discussion of this amplifier as which is used. Such triggered vibrations

only noise signal source can be considered. Most annoying when there are sudden changes in the

the clamps of the playback head may be the noise polarity or amplitude, and the amplitude of these

signal 40 to 60 decibels below the signal A ₀ , oscillations is proportional to the size of this

d. H. there may be an amplitude ratio of 1: 100 40 sudden changes.

up to 1: 1000. If one assumes the smaller id represents a property of the non-linear ratio and further assumes that a larger one represents that its gain decreases with decreasing signal in the noisy band before the non-signal amplitude, and since the linear gain initiated has an amplitude equal to the one-oscillations are always of a smaller amplitude than the noise signal may have, that is, an amplitude of the size 0.01 A ₀ may be present, so that a further reduction in the amplitude is the amplitude the same signal is reached at the exit. In the case of a quadratic amplifier output of the non-linear recording amplifier, an oscillation amplitude of 10% is reduced to an amplitude of 0.1 A ₀ , that is to say, it is reduced by an Am-1%.

amplitude of 20 db above the noise signal. In the present description, means given. It is of course assumed here that the "instantaneous value of the amplitude" is the absolute noise signal level after equalizing the instantaneous magnitude of the voltage or the measured. Current of the signal regardless of its fore-if the useful signal and the noise signal of- sign. It is not the signal as such, which would be completely independent of each other, so when recorded to a fractional power the signal level would be 0.1 after squaring it and when reproduced to a power greater than with its original amplitude of 0.01 A ₀ appear, one is raised. If this were the case, while the noise signal _{would appear with 0.0001 A 0} , the reciprocal exponent would be 0.5, for example, with the hundredth part of this amplitude and 2, and the sign of the recorded tude or with a value of 40 db smaller amplitude. The signal would be indefinite and that of the signal reproduced as a statistical signal would always be positive. Actually occur at the peak of the useful signal, so that a possibility changes, however, every recorded or instantaneous value of the amplitude of 0.11A ₀ recorded signal can have the same sign, which after its squaring is a timely with the signal which is at the input of the does not result in an amplitude of 0.0121, ie that a noise 65 linear amplifier is located. The magnitude of the signal component signal of about Ve the amplitude of would include its exponent, which would not be present as a whole. This means the parameter is directly affected. Although, however, that the useful signal, instead of completely in which the amplitude is the maximum value of the

9 10

represents voltages or currents appears to be constructed in a known manner. One of these the expression »momentary amplitude or» eye possibilities is a second differential amplifier, visual value of the amplitude «the most appropriate to which the signals from one of the two channels To be expression. Furthermore, a switching element with reversed phase position changes so or a unit, which the instantaneous value of the 5 that the addition by subtracting a nega-amplitude influenced in the desired way, tiven size is effected. The combined signals, at the same time and necessarily also the maximum amplification, which means both the linearly amplified low tude in the same way and vice versa and therefore frequency components as well as the nonlinear verist the term "amplitude" contains high-frequency components in certain amplitudes, which are interrelated also in place. io to a known recording head 17

F i g. 1 shows a block diagram of a system for being guided so that it can be carried on the recording tape 19 the recording of television signals; recorded in the usual way.

F i g. 2 shows the corresponding circuit diagram of a system in which the one used here

Playback equipment used with the system setup is a tape splitter F. i g. 1 recorded signals; 15 process has been used, by which the maximum

F i g. 3 is a schematic circuit diagram of a frequency to be recorded, reduced by half, whose output amplitude was practically produced. Since the television band has a width of proportional to the square root of the input signals is 4 MHz, the band splitting is the is and maximum recordable and reproducible

F i g. 4 is a schematic circuit diagram of a 20 frequency limited to 2 MHz. When these signals amplifier, which delivers signals at its output terminals during playback to the terminals of the pickup, which occur in amplitude proportional to the head, the cutoff frequency is around Square of the amplitudes on its input side three decibels lower than the maximum sensitivity are. and is therefore around 1.2 MHz. The characteristic curve falls

In the circuit according to FIG. 1 can produce a signal from this value quickly up to the absolute limit source 1 a television recording camera or below frequency at which the sensitivity is zero also be a television receiver. Which wears off and which is slightly above 2 MHz. Output signals from source 1 reach a line. The equalization circuits are armed tion 3, and this line can either be fully tuned to the frequency of 2 MHz and cut continuously Television signal with inclusion of the equals 3 ° from those above this frequency value sharply. That Leading current components or a television signal, frequency band from 1.2 to 2 MHz is the same which is the noisy part of the signals called the lowest frequency components. have been removed by a blocking capacitor, the low-pass filter 5 is therefore dimensioned so that it so that it cuts off sharply at the frequency 1.2 MHz in the usual way later, Need to become. When the signals to be recorded 35 at the time shown in FIG. 2 shown reproduction of a Are subjected to frequency band division, device, the recording medium 19 is the same the signal source 1 is the establishment of a channel, as in Fig. 1. Each method step in the playback which such a process takes place. Since the process has its corresponding procedural step Maintaining exact phase relationships during recording. So it is for each of these is of the utmost importance for television signals, a device must be required in 4 ° process steps, that for the division of the signals into two channels, which are either identical to the one in the recording of where one is the low frequencies and the channel used or the dual radio carries the high frequencies, uses filtering. The relevant components are network must be such that the phase delay in FIG. 2 by the same reference numerals as tion is directly proportional to the frequency. This leaves 45 in Fig. 1, which, however, has been provided with a prime in the case of low-pass filters (Gaussian filters) relatively the indicated.

easy to achieve, but is not possible with high-pass filters. The signals recorded on the tape 19 are

just as easily possible. In the preferred version removed by a scanning device 17 ', The embodiment of the invention is therefore the embodiment which can be implemented in the same way as the sampling output voltage the in F i g. 1 with 1 designated 5 ° device 17 in F i g. 1 and in many cases even the signal source two channels supplied, of which the same scanning device can be. When playing one a low-pass Gaussian filter S and the other one supplies this scanning device with its signals first Delay line 7 contains, which all to an amplifier 21.

Signal band by the same amount of microseconds In a practical implementation, this contains

delayed as him the low frequencies in the 55 amplifier several stages that are in the same ver-line 5 experience. Stronger housing can be accommodated. Preferential

The signals of both channels are in a dif- ferent way which is supposed to equalize the overall level of the interference amplifier 9 reunited with each other, take place in signals taken at this point, which the signals supplied by the filter S from so that the low-pass filter 5 'and the delay dem The entire signal frequency band is subtracted from the signal line 7 'supplied to the signals that are recorded, so that only the high frequency components remain with the same relative amplitudes. These occur on the output side of the tuden like the signals sent to the recording differential amplifier and are a not nungskopf 17 in F i g. 1 are fed. They de-linearize Amplifier 11 is supplied. At the same time, however, the noise signals are also retained, the signals supplied by the filter 5 to a 65 which arise in the preceding stages. That linear amplifier 13 supplied. The output filter 5 'and the delay line 7' must large of these two amplifiers arrive at an electrically identical to the filter 5 and the lei adding circuit 15, which can be in any respect 7 in FIG. 1, and the same applies to that

11 12

Differential amplifier P '. Because most of the unification. For illustrative purposes, corresponding directions used for recording are shown in circuits in FIG. 3 and 4 shown,
can also be used for the playback process. In the circuit according to FIG. 3 If the output is possible, these circuit components only need to be present in many cases of the differential amplifier 9 in the grid in some cases, and 5 five-pole tube 23 is fed in. These tubes have the property that their dynamic internal resistance to the recording side on the playback side is very high and that their anode current is switched on. The linear amplifier 13 can also be constructed in the same way as the playback proportional to the control grid voltage is made half of a considerable working range. io den can. The internal resistance of these tubes

The amplifier 11 ', however, exercises the reverse can therefore be regarded as infinite, and the Effect like amplifier 11. It does not work. Amplifier output voltage is directly proportional like amplifier 11 after a square root to the resistance of the load circuit. When forgetting but rather after a quadratic strengthening of high frequency components can the-law. So there occur on its output side amplifiers load circuit resistance not made too large t, which become the square of the input ampli-, since otherwise the inevitable shunt tud correspond. The components 1Γ and 13 'leave capacities inevitably lower the high frequencies at the adder circuit 15 ', whose output weaknesses. In the case of the scarf size shown in FIG a display of the recorded signals shows the anode voltage and the screen. In the device described here, the grid voltage is obtained from an ordinary direct current this output signal is related to a decoding source, and the anode receives its rectifier, which the tape splitting process, the voltage across a resistor 25 of 3000 ohms, had taken place before the recording, again because it was found that at this value reverses. However, since this has nothing to do with the anode resistance, the output characteristic up to has to do is this subsequent device in the 25 runs horizontally to the cutoff frequency of 2MHz. Drawing not shown. The anode load circuit is via a block

In the device described, the capacitor 27 are connected, which is chosen as large

Signals of the noisy channel only one one is that it is within the frequency band from 1.2 to

Zig channel fed to which the low-frequency 2 MHz has a negligible impedance

and carries relatively noise-free signals. It represents 30. The load circle itself consists of two

should therefore be recognizable that the high-frequency oppositely polarized crystal rectifiers 29,

components of the amplifier 1Γ also to more than that are parallel to each other and led to earth

can walk a low frequency channel and are there. In the embodiment described here

run through individual adding circuits. Two rectifiers »Hughes IN 191« were used to

However, it is possible to simplify the drawings, which have the same characteristics and

genes and the description are not shown with. are suitable for high frequency. It is

In the above description of the block with point contact rectifier. The rectifiers

In the circuit diagram according to FIGS. 1 and 2, the 29 should not have been carefully selected in relation to one another

linear amplifiers 11 and 11 'only by theirs, since the characteristics of such rectifiers are not

Functions marked. The filters that delay 40 turn out to be as uniform as those of vacuum

power lines, the linear amplifiers and the tubes. The high voltage side of these two direct

Differential amplifiers are just like the recording lights with the grid of another amplifier

connection heads and take-off heads so well-known tube 31 connected. The anode of the tube 31 becomes

Switching elements that their description is superfluous via an ordinary load resistor 33 from the

appeared. Squaring and square rooting circuits 45 fed by the same source of direct current as the anode

are also known. Various circuits of the tube 23 and the connection to the adder

for squaring and square root, some of which circuit 15 includes a block capacitor 35. The

are more or less complicated, are in the tubes 23 and 31 are in the usual way

Book "Waveforms", Vol. 19, Radiation Laboratory Cathode Resistors 37 and 39 biased. These

Series (McGraw-Hill, 1949), on pages 678 50 Resistors are not parallel capacitors

to 693, and it is there also said that provided so that the tubes within certain

some of these circuits also target third roots through the resulting negative feedback

can hen. For the amplifier 11, either of them can be stabilized.

The square root circuits described there are known to change the one crystal equation

are applied and for the amplifier 11 'each of the 55 rectifier traversing current approximately with the

squaring circuits described there. Square of the voltage applied to the rectifier,

It is not necessary that the amplifier 11 'and, as a result, the signal at such an equivalency provides a signal which corresponds to the square root of the component voltage lying in an integer converter, provided that only the exponent of the rectifier current represents. Each of these determinations represents amplifier 11' The reciprocal of amplifier 60 is equivalent to stating that FIG. 11 represents. It is also not necessary for the effective resistance of the device to change inversely to size n, that is to say the exponent in the amplifier 11 'that the applied voltage has in the relevant half amount 2, if it is only greater than 1, although the wave changes in which the rectifier is permeable to the improvement in the ratio. In the blocking half-wave, the resistance of the useful signal to the noise signal changes in the same way, each 65 in the same way, but is so much higher that the exponent in the amplifier 11 'is made larger and can be neglected in the present case. These facts increase the application of the impedance of each rectifier 29 is the scope of the invention and facilitate their implementation for signals whose amplitudes in the vicinity of the

Claims (1)

13 14 Noise signal levels are much smaller than the 42 the same relationship to the effective resistance of the Resistance 25. As a first approximation, one can therefore have rectifier network 45 like the conductance of the say that all the signals supplied by the tube 23 of the resistor 25 to the conductance of the rectifier 29, the resistors of the rectifier prevail, and are thus the properties of the resistors in both the output current of the tube proportional to its 5 the cases the same and the outputs of the Input voltage is also the voltage to the rectifier have the desired properties rectifiers, which is located on the tube 31. For this it is necessary that the resistor 47 tional of the input voltage of the tube 23. It is small in relation to the minimum resistance of the so it is proportional to the square root of the two grid rectifiers. The resistance of the DC voltage of the tube 23. io richter can be increased by having one in each In reality, however, this is not strictly true. Branch of the rectifier network a series Bei small signal amplitudes where the effective connection of two or more than two rectifiers Resistance of the rectifier is high, a larger is used. This also makes a comparator better A fraction of the current reached by the resistor 25 moderation of the rectifier characteristics, derived, since the anode current of the tube 23 15 because then the two series connections are also reversed how to divide the resistances. When one has to be compared and not accepted that the rectifier characteristics are a single rectifier. Obey quadratic law, so the other nonlinear elements can change in place The voltage lying on the grid of the tube 31 is not used by the rectifier in the circuit, exactly according to a square root law, ie, the 20 provided that the dependence of its current exponent on A ₀ is not exactly 0.5, but on its voltage in a way runs, which is a bit bigger. However, it is still considerably smaller than one, suitable for the high frequencies to be treated. The same applies if it is used. If its characteristic curve is symmetrical to the voltage of the crystal rectifier, a cubic characteristic curve or to the current, one can also have individual ones or a characteristic curve with a different Ex-25 such switching elements instead of the components shown as two. Use rectifier networks. The used In order to reproduce the signal in a satisfactory manner, it is necessary that the nonlinear amplifiers b and Vb, but amplifier 11 'can be as closely as possible, an exact reci- this by the amplification of previous ones or proke property like amplifier 11. This compensates for 30 subsequent amplifiers. It can be achieved by also using a circuit in which the gain or attenuation is practically dual of that of the linear low frequency channel corresponding to amplifier 11, ie a circuit in which measure. the resistances through conductance values, the currents through Tensions and vice versa are replaced. One of the particular reciprocal enhancer non-type enhancers described is shown in FIG. 4 shown. In this, the only amplifier and circuit that can be used for this purpose, the input tube 41 is supplied with the signal of the also not necessarily the best amplifiers for a differential amplifier 9 ', which are particularly used as tubes. In the present description with output resistance in its cathode lead, this is the only reason why it is interconnected. The property of this circuit is treated more closely to show that the invention consists in the fact that its output resistance is low and that the voltage of the cathode can be carried out directly in proportion to the structure.
tional to the voltage of the grid fluctuates, so it should also be noted that the circuit in changes practically independently of the current. This applies to FIG. 1 also for purposes other than recording, provided that the impedance 45 of signals from the adder circuit 15 on the output circuit can be used relatively high in the recording medium 19. One is equal to the internal resistance of the tube, instead of, for example, using the signals of the adding circuit to be small compared to it, as in the recording 15 for modulating a carrier wave. The voltage amplifier. The tube current flows through the modulated carrier wave can then be transmitted wirelessly or cathode resistance 42 from an even higher resistance 50 via a coaxial cable. The direct current component of the output there can be the modulated carrier wave in the usual signal is received and rectified by a blocking capacitor 43 under way, in order to recover the modulation voltage in the frequency range used. The modulus represents negligible resistance. On the cation voltage, a block capacitor can then follow the amplifier 21, two rectifiers 45, the 55 in FIG. 2 corresponding stage are fed,
are opposed to each other, but to that Block capacitor are in series and not as in claims: F i g. 3 are led to earth. A resistor 47 is led to earth behind the rectifiers, 1. Method for improving the signal-to-noise ratio measurement live end on the grid of the 60 of the sent in and at a remote location duct 49 is located. This latter tube is over received or recorded and again a resistor 51 biased. played, here mainly in a The load circuit of the amplifier 11 contains the correct frequency range of the occupied that is, conductance values in parallel with a source of constant frequency band overlaid by interfering signals Stromes, and the load circuit of the amplifier 11 '65 message signals, in which a part of the contains resistors in series with a source con- frequency band separated from the message signal constant tension. If the sum of the re-separates and is processed separately, preferably standes 47 and the effective resistance of the tube wise for a magnetic storage of I 204 Television signals, characterized in that that the separated area of the frequency band before sending or recording a subject to nonlinear gain with an exponent less than one and with the remainder of the signal is recombined and that after the reception or reproduction of the message signal the frequency range is again separated from the rest of the signal, a non-linear amplification with one of the exponents mentioned subject to reciprocal exponents and then again before the signal is processed is combined with the rest of the signal. 2. The method according to claim 1, characterized in that the first exponent is about V2 and the second exponent is about 2. 3. Sending or recording device for performing the method according to claim 1, characterized in that separating devices (5, 7, 9) are present which separate said frequency range from the remainder of the tape, that a non-linear amplifier (11) for amplifying the signals of this Amplify the frequency range according to the law ^{bA 1} '" and that an adder circuit (15) is present for adding the output of the non-linear amplifier to the signals in the rest of the frequency band mentioned. 4. Receiving or reproducing device for performing the method according to claim 1, characterized in that separating devices (5 ', 7', 9 ') for separating said frequency band range from the remainder of the band, furthermore a non-linear amplifier (U') for amplifying the signals of said frequency range according to the law (l / b) A ^{n is} present and that an adding circuit (15 ') for adding the output variable of this non-linear amplifier to the signals in the mentioned band remainder is present. 5. Device according to claim 3 or 4, characterized by a linear amplifier (13 or 13 ') to amplify the signals of the remainder of the tape before they are fed to the adder circuit (15 or 15 '). 6. Device according to claim 3, 4 or 5, characterized in that said separating devices include a low-pass filter (5, 5 ') for separating the lower part of the frequency band, further delay devices (7, T) for delaying the signals of the entire band around the same Amount, as it occurs in the filter, are present and that an arrangement (9, 9 ') is present for subtracting the output variable of the filter from the output variable of the delay means in order to obtain the upper part of the frequency band. 7. Device according to claim 6, characterized in that the subtraction arrangement a differential amplifier (9, 9 '). Considered publications:
German Patent Nos. 865 325, 658 976;
German interpretative publications No. 1 094 797.1096 955. 1 sheet of drawings 509 737/249 11.65 © Bundesdruckerei Berlin