US1955681A

US1955681A - Negative impedance repeater

Info

Publication number: US1955681A
Application number: US379017A
Authority: US
Inventors: Mouradian Hughes
Original assignee: Individual
Current assignee: Individual
Priority date: 1929-07-17
Filing date: 1929-07-17
Publication date: 1934-04-17
Anticipated expiration: 1951-04-17
Also published as: USRE19305E

Description

April 17, 1934. H. MOURADIAN 1,955,631

NEGATIVE IMPEDANCE REPEATER Filed July 17, 1929v 2 Sheets-Sheet 1 lnpuf Currenf owjouf Cur/'enf Line Line L Wesf' (Y) 5867 IN VENTOR.

A TTORNE Y.

April 7, 1934. H. MOURADIAN 1,955,681

NEGATIVE IMPEDANCE REPEATER Re/af/ve i g i I 60 i N l g g Q 8 E 5 "a E E w 1 5 k E 5 I WITNESS: INVEN'I'OR ATTORNEY Patented Apr. 17, 1934 UNETED STATES NEGATIVE IMPEDANCE REPEATER Hughes Mouradian, Philadelphia, Pa.

Application July 17, 1929, Serial No. 379,017

11 Claims.

This invention relates to repeater systems and, particularly, to the use of negative impedances as the amplifying and distortion correcting elements of such systems.

This application is a continuation in part of my earlier application, S. N. 188,497, filed May 3, 1927, on Transmission systems.

Where, as in the case of the circuits used in the present art, the total attenuation of a section of transmission line is substantially constantfor a band of frequencies, then a gain which is nearly constant for said band of frequencies may be introduced at proper intervals through the use of vacuum tube amplifiers arranged in a two-way repeater system. This arrangement is the one now used in the art. It suiiers under the handicap that, even with comparatively light loading of the telephone conductors-.044 henry loading coils spaced 1.2 miles apart, the attenuation constant of the section of transmission line between telephone repeater stations rapidly builds up for frequencies near the'so-called cutoff point 01 the line. I have discovered a new method for introducing a gain in a telephone transmission line which may be automatically varied with frequency. In addition to introducing a gain, said gain may also be varied to avoid distortion effects which are cumulative in eiiect and hence most severe on the longer lines. In the present application, the disclosure herein made indicates the underlying basic idea as applied to the simpler case of a constant gain.

In accordance with my invention, I obtain a result which is substantially equivalent to that obtained by means of a repeater of the 22-type, which is well known in the art. By making use of negative impedances as the amplifying elements, I am able to utilize devices for this purpose which, from their fundamental nature, possess the negative impedance property, such as the dynatron, which is described in an article entitled The dynatron, by Dr. Alb. W. Hull, which was published in the Proceedings of the Institute of Radio Engineers, February 1918. Other forms of negative impedances which may be used in conjunction with the present invention are those disclosed in the following U. S. A. Patents: 1,606,350, Negative resistance, M. M. Dolmage; 1,779,126, Negative resistance circuits, F. H. Graham; 1,779,380, Negative impedance circuits, H. W. Dudley; 1,779,382,Negative impedence circuits, R. C. Mathes.

All of the above negative impedance devices are of the constant impedance type. These devices develop constant negative impedance characteristics provided, of course, the batteries associated with them are maintained substantially constant. In the case of the dynatron, the

negative, resistance characteristic, as fully deshows a form of negative impedance device that may be substituted for the impedance shown symbolically in Figure 1. An equivalent impedance network to that shown on Fig. 1 is shown are connected in a 11' formation. Fig. 4 shows the variation of the amplification obtained when use is made of the arrangements of either Fig. 1 or Fig. 3 when the line impedance differs from its average value. ception of the use of neutralizing networks at recurrent intervals, each neutralizing network representing a negative impedance amplifier.

' Figure 1 shows a network consisting of two the principle underlying the invention, Figure 2 :7

on Fig.3. In this case the impedance elements Figure 5 shows thebroadconequal impedances X and a third impedance Y- then, the impedance looking into the left-hand terminals of the network is equal to the impedance of the line. The same relation exists also between the impedance looking into the righthand terminals of the network and the line impedance. From the diagram of this network it is seen that the ratio of the current I2 to I1 is given by the following relation:

Solving Equations (1) and (2) for X and Y, we obtain these equations, it is evident that there will be no reflection of the wave at the terminals of the network since the impedance looking into the network in each direction equals that of the line to which it is connected, while the transmission loss corresponds to current ratio (11.). This transmission loss can be expressed in transmission units in accordance with the following for mula:

in which L is the transmission loss in db.

In accordance with my invention I desire that the network shown in Figure 1 should possess the property of giving a transmission gain. In other Words, the loss L must be negative. In order to make L negative, it is evidently necessary that (n) be made greater than unity, although it makes no difference whether (n) is positive or negative.

Now it will be seen by Equations (3) and (4) that if n is made greater than 1 and positive, the impedance (X) and (Y) become negative; while if (n) is made greater than 1 and negative, the impedance (X) becomes negative and (Y) becomes positive. Hence it is seen that by making some or all of the impedance devices which constitute the network shown in Figure 1 negative, the network is made to possess the property of giving a transmission gain. It is furthermore apparent that by choosing values of (X) and (Y) in accordance with Equations (3) and (4) the impedances looking into the network from either direction (as given by Equation (1)) will be positive and equal to the line impedance. From this it is evident that if the network of Figure 1 is thus properly proportioned, a wave reaching the network from either section of the line will be amplified and transmitted into the other line section, while no reflection will take place at either terminal of the network. Consequently there will be no echoes set up by the action of the network.

While the network shown above consists of three two-terminal impedance devices arranged in the form of a T, it is well known in the art that the behavior of any network of such twoterminal impedance devices can be completely matched by the behavior of a T-shaped network containing three properly chosen devices as shown in the figure. Consequently, in discussing the behavior of the T-shaped network, I have described the behavior of any possible combination of two-terminal impedance devices which can be assembled to produce the desired effect of amplifying the waves transmitted through the network without setting up echoes due to the action of the network.

In illustration of the point just made it may be shown that the network elements might be arranged in a 1r instead of a T as hereinabove outlined in detail. The pillar elements, in such a case, would have to be negative impedance devices, while the architrave might be either a positive impedance or a negative impedance device. In the case of a network arranged on a 11' basis, the values required are, using the same notation as hereinabove- Architrave e1ement=Z (6) 1 7 Pillar element=Z t2 (7) tion requires that some or all of the impedances be negative.

The amplification of the network shown in Figure 1 of the drawings varies with the impedance of the line, being equal to (n) when the line has its average impedance (Z0). If the two lines connected together by means of the network have equal impedances, but diiierent from their average value Z0 which was used in deriving the constants of the network as given by Formulas (3) and (4), then there will be some reflection on electric waves reaching the network from either the left hand or the right hand side of the terminals of this network. The ratio of currents of Formula (2) does not represent the true or complete effect of the network. Obviously Formula (1) does not hold either, since only in the case where Z in that formula has its average value Z0 will that formula hold. It is evident that the true amplification is given by the change in line current at the receiving end under the following two conditions.

(a) When the network is eliminated entirely and the two lines having equal impedances Z are connected together.

(I?) When the network, designed on the basis of some average line impedance value Z0, is interposed between the same two lines.

If the network is eliminated completely, assuming an electromotive force (E) impressed upon the left hand side of the circuit, the current I into the right hand side is given by If, now, the network is interposed, the current into the line at the right hand side of the network is given by the relation The change in current NIH It must, of course, be assumed throughout that When Z is given its average value Z0, the variable amplification coefficient (m) becomes equal to normal design value (n), as shown below:

It will be seen immediately that the variable amplification (m) becomes infinitive for two different limiting values of line impedance Z1 and Z2, as follows:

The product of the two values of line impedance, each of which results in infinity ampli fication is equal to:

It follows, therefore, that a predetermined value (n) for the amplification is obtained, provided the line impedance does not depart appreciably from its average value Z0. If the two lines vary in impedance-still staying equal to each otherthen the amplification gradually increases until it reaches infinity for two values of line impedance, one greater than Z0 and one smaller than Z0, their product being equal to 20 as given by Formula (12).

Figure 4 of the drawings shows in graphical form the value of (m) as obtained from Formula (11). In this figure the value of the line impedance Z is shown in abscissa and (m) in ordinates. The curve as shown, has a minimum corresponding to real amplification and a maximum which does not represent any amplification. The maximum corresponds to the case where the impedance of the line has changed sign and has now the same sign as the negative impedance elements of the impedance network of Figure 1 of the drawings. The numerical values of Z which result in a. maximum or minimum for (m) are obtained by differentiation of (m) with reference to Z, which gives, after some simplification;

In Formula (13) the ratio ('r) is given as a function of (n). In practice, the opposite situation arises. It is usually desired to find out what the amplification (n) for normal or average line impedance would be, if we know beforehand the maximum variation (1) in line impedance that is likely to be encountered. Solving Equation (13) for (n) we get:

This is exactly the amplification that is now possible to obtain in the art through the use of the well known 22 type telephone repeater circuit. It is therefore clear that the arrangement shown on Figure 1 of the drawings is an exact equivalent of the arrangement now used in the telephone art in conjunction with two-wire circuits. It is limited as to its range of use within exactly the same line impedance variations as its present equivalent in the art. It will give a constant gain as measured by Formula (5) for that band of frequencies for which the average line impedance Z0 is substantially the same. It will sing and cease to be a repeater when the line impedance variation (r), for some one frequency, exceeds the limits given by Equation (13) That particular frequency will limit the band of frequencies for which the repeater is an effective instrument of amplification. It will also be noted that the arrangement first described in these specifications, is the first known to the art using constant negative impedances in network ar-' rangement. Other arrangements have been described by earlier inventors which depend upon the variations of the negative impedances, or of the positive impedances (in the form of ionized gas resistances) or of both types of impedances to secure amplification. When use is made of the arrangement, as first disclosed in these specifications, only constant impedances are required. It is also the first truly amplifying arrangement known to the art which makes use of just three (3) impedances arranged in either T or 1r network, substantially as hereinabove described.

It has been pointed out hereinabove that, though the network herein described may be composed entirely of negative impedances, its characteristic impedance nevertheless is positive and can be made equal to that of the positive characteristic impedance of the signaling system with which it is associated. That'requirement is expressed analytically by Equation (I). If that equation is solved for (Zn), in function of the network impedance values (X) and (Y), we find If in the above the values of X and Y, as obtained from Equations (3) and (4) are substituted, an identity is obtained. Now, though (X) and (Y) may both be negative, it is readily seen that the numerical value of the terms (X +2XY) will be positive. It is important to note further that, if the two architrave impedances (X) are negative, (Y) may be positive, as already indicated in the discussion following Equation (5), and the T network will still operate as an amplifying system. This fact, the development of a positive characteristic impedance in a network of three impedances, some or all of which are negative, is the key to the possibility of using negative impedances as an amplifying system. It may also be pointed out here that any two-way amplifying system whatsoever using negative impedances can be reduced to the two fundamental prototypes-the T and 1r networks as herein disclosed.

There are a great many ways which are well known in the art whereby a two-terminal device which will have the desired negative impedance property may be obtained. One of these is illustrated in Figure 2, which shows the circuit of the dynatron, previously mentioned, when used as a negative impedance. The dynatron (Proceedings of the Institute of Radio Engineers) comprises a filament (1), a plate (2), and an anode (3), having an opening therein through which electrons pass from the filament to the plate. Thetheory underlying the operation or" such devices is fully disclosed in said proceedings and, for simplicity, will be omitted from this specification. The terminals a-a' should be connected with the line L at the correspondingly designated terminals shown in Figure 1.

' Certain outstanding advantages of the amplifying system using negative impedances as herein disclosed will be apparent to those who have a knowledge of the practices in the art. As com-- pared, for instance, with the two-way 22-type repeater system now so universally in use, the system first disclosed herein does not interrupt the continuity of the circuit. It is thus possible to transmit battery signals or dialing impulses through the amplifying system. This is not now possible with the 22-type standard repeater system. Similar advantages hold as regards the transmission of telegraph signals through the repeaters. Where it is necessary to provide any of the features just mentioned, it is now necessary to provide complicated and expensive equipment bridged around the telephone repeaters of the 22-type. In addition, the overall power efiiciency of the system as herein first described is twice as good as the overall power efliciency of the 22-type system on account of the losses encountered with the latter in the balancing networks.

While the invention has been disclosed as embodied in a particular form, it is capable of embodiment in other and different forms within the spirit and scope of the appended claims. For instance, a negative impedance using ordinary vacuum tube amplifiers and ordinary wiring and battery supply arrangements may also be obtained through the application of the arrangement disclosed by Latour in U. S. A. Patent 1,687,253. This arrangement describes a twoterminal network which develops a constant negative impedance and is suitable for use with the invention first described hereinabove.

The specifications as hereinabove outlined fully describe the operating characteristics of a two-way telephone amplifier using negative impedances as the constituent parts of such an amplifier. It has been shown (see Formula 14) that the amplification obtainable by the arrangement first disclosed in these specifications is exactly the same as that now obtained by the use of two-way telephone repeaters known as the 22 type. The negative impedance repeater as herein disclosed may therefore be substituted for a 22 type repeater of the present art in any transmission circuit. As well known, such repeaters may be used in tandem arrangement in any number without mutual interference. Consequently, the negative impedance repeater described hereinabove can also be so used at recurrent intervals. It is customary at present to space telephone repeaters at tit-mile intervals in voice frequency cable circuits, and such spacing will prove equally economical with the type of repeater first outlined hereinabove. It is expected further that the use of the repeaters of the new type will prove less susceptible to singing in view of the absence of local circuits similar to those typical of the 22 type circuit, wherein the outgoing circuit east of the repeater sends through an unbalance current to the incoming circuit of the west repeater.

In Figure 5 of the drawings is shown an arrangement originally filed on May 3, 1927 as Figure 4 of the drawings of S. N. 188,497, now abandoned. The present application is a continuation in part of the above prior application. This figure shows the broad conception underlying the present invention, i. e., the use of negative impedances forming an artificial network representing the exact negative of the equivalent network of a section of natural transmission line. When such neutralizing networks are inter posed in a transmission line and the constituent parts thereof are duly proportioned with respect to the constants of said transmission line, it is possible to completely neutralize or eliminate the effect of the presence of a transmission line between any two distant points. The effect of such an arrangement therefore is the realization of an ideal, that of aso-called zero-loss line. When the conception underlying Figure 5 of the drawings is carried through to its theoretical limits, not only is it possible to obtain amplification, a desirable objective by itself (but it is also possible to obtain distortionless transmission, in that both attenuation and phase change will evidently be the same for all frequencies. This is clearly shown by the arrangement of Figure 5 of the drawings, wherein the equivalent 1r network of a natural transmission line is illustrated as connected to

terminals

1, 2, 3 and 4, while the corresponding neutralizing type network is connected to terminals 5, 6, '7 and 8. The two shunt impedances (+Z1) of the equivalent network of the line are neutralized by the corresponding two negative shunt impedances (-Z1) of the artificial network. The series architrave impedance (+Z2) is also neutralized by the corresponding series negative impedance (Z2) of the artificial network, as shown. The result, so far as transmission is concerned, is simply that the natural line, for all practical purposes, has been removed from the transmission path. Everything happens as if the generator at the originating end and the receiving equipment at the distant end were connected by a line of zero length. Such a line, naturally, ofiers neither attenuation nor phase change effects. We have thus removed or eliminated distortion as well as attenuation.

It is clearly necessary, in order to carry into practice the conception underlying Figure 5 of the drawings, to have available negative impede-noes, marked on said figure as (Z1), (Z2), etc. In U. S. A. Patent 1,687,253, granted to Latour, is shown a general method for obtaining negative impedances of any type. Other inventors, as previously mentioned in these specifications, have also shown similar methods for obtaining negative impedances.

Since the equivalent network of a section of transmission line, such as shown connected to

terminals

1, 2, 3 and i of Figure 5 or" the drawings, represents a so-called transmission loss between terminals 1, 2 and

terminals

3, 4, it follows that the artificial neutralizing network connected to

terminals

5, 6, 7 and 8 represents a so-called transmission gain. Any device in the art which introduces or is responsible for a gain is also designated as a repeater or amplifier. The artificial network connected to

terminals

5, 6, 7 and 8 is in effect a negative impedance repeater. It is more complicated in type than the usual type repeater,

since to realize it in practice it is necessary to obtain the negatives of impedances of general type, instead of providing only a negative resistance. To make this point absolutely clear, Figure 19 was provided in my prior application, S. N. 188,497, showing what might be, for a given case, the constituent parts of impedances (+21) and (+Z2) whose negatives it is necessary to supply for the purposes indicated above.

In the present specifications, the simple case of an amplifier inserted in a loaded cable circuit was outlined in detail. Such loaded cable circuits, as well known, have a negligible reactance component, when properly terminated, and an amplitying system built on the basis of negative resistances only is satisfactory in such a case. The application of the broad underlying principle of the present invention is not, however, restricted to communication circuits which have characteristic impedances with zero or negligibly small reactance component, as fully explained hereinabove. Ihe general design features, as fully outlined in the present specifications, apply with equal force to the general case where the constituent parts of the 1r structure representative of a section of transmission line are impedances of general type. For instance, Formulas (6) and ('7) of the present specifications apply to the general case represented on Figure 5 of the drawings. As shown, the only negative impedances which it is necessary to provide are impedances which are numerical multiples of (-Zo), where (+Zo) is the characteristic impedance of the natural transmission line. It has been shown hereinabove that the characteristic impedance of the artificial network can be made equal to that of the natural line, even though the artificial network has only negative impedances as constituent parts. It may be further stated that, of necessity, the propagation constant of the same artificial network, when designed as shown on Figure 5 of the drawings, is equal in absolute value but exactly opposite in sign to that of the corresponding section of the transmission line, since with full neutralization the current at the beginning and that at the end of the composite transmission system illustrated on Figure 5 must be equal both in amplitude and in phase.

Reference may be made, for a more detailed exposition of the underlying principles involved in the present invention, to a paper presented by me in April 1928 before the Franklin Institute of Pennsylvania (published in the journal of the same institute in February 1929).

I claim:

1. A system of electrical wave transmission interposed between two telephone offices, consisting of a telephone line out into sections at recurrent points by a system of series and shunt impedances, said impedances in combination representing at each cut a section of artificial telephone line of opposite series and shunt characteristics to those of the actual line. i

2. A repeating amplifier comprising a plurality and its shunt elements in accordance with formula wherein n=a numeric greater than unity.

5. A 1.- network of impedance devices for connection to a signaling line of average impedance Z0, having its pillar elements equal to and its architrave element equal to where (n) is a numeric greater than unity.

6. A T network of constant impedance devices, some or all of which are negative, for connection to a signalling line, having a characteristic impedance equal to the characteristic impedance of the signalling line.

7. A 1r network of impedance devices, some or all of which are negative, for use in combination with a signaling line, said network having a characteristic impedance equal to the characteristic impedance of the signaling line.

8. In a signaling system, the combination with a line of a repeating amplifier interposed between sections thereof, said amplifier comprising a constant negative impedance device in series with each section of said line section and a constant positive impedance in shunt with said line.

9. In a signaling system, the combination with a line of a repeating amplifier interposed between sections thereof, said amplifier comprising a constant negative impedance device in series with each section of said line and a constant negative impedance in shunt with said line.

10. In a signaling system, the combination with a line of a repeating amplifier interposed between sections thereof the said amplifier consisting of a combination of series and shunt negative impedances.

11. In a signaling system, the combination with a line of a repeating amplifier interposed between sections thereof, the said amplifier consisting of an electrical network having a characteristic impedance equal to the characteristic impedance HUGHES MOURADIAN.