US1511423A - Electric-current transmission - Google Patents

Description

D.A.QUARLES ET AL ELECTRIC CURRENT TRANSMISSION Filed AD il 30, 1923 it.

vPatented Oct. 14, 1924.

UNITED STA-res V 1,511,423 PATENT on-"lca.

DONALD A. QUARLES, OI ENGLEWOOD, I'm MOHR, 01' EAST ORANGE, NEW

JERSEY, ASSIGNORS TO WESTERN ELECTRIC COKZANY, INCORPORATED, OF NEW YORK, N. Y., A CORPORATION 02 m YORK.

ELEGTRIO OURREKT TRANSIISSION.

Application filed Aprl1 30, 1928. Serial No. 635,419.

To all'whom it may concern:

Be it known that we, Do'NALo A. QUABLES and FRANKLIN Mornz, citizens of the United States, residing at Englewood, in the county of Bergen, State of New Jersey, and East Oran e, in the county of Essex, State of New ersey, have invented certain new and useful Improvements in Electric-Current Transmission, of which the following is a full clear, concise, and exact description,

This invention relates to electric current transmission, especially to repeating telephone currents, and aims to accomplish such repeating eificiently and without undue distortion. i i

In accordance with the invention there is associated with a transformer, such for in-' stance as the input transformer of an .electron tube repeater, a compensating reactance -2 for resonating with the efl'ective reactance across the secondary winding of the transformer, to prevent that efiective reactance from .unduly attenuating currents of high frequenc for instance, the hi her frequencies of t e voice range, and time degree of compensation effected is controlled by effectively shunting a part of the compensating reactance with a resistance to control the sharpness of the resonance. Over compen- 0 sation may be effected when desired, as for the purpose of correcting for distortion due 1 to unequal attenuation of currents of differj ent frequencies in the line, or for the pur se of correcting for the attenuation effected by 36 the repeater filter at frequencies in the transmitted range but, close to the range of highly attenuated frequenciesand the repeater may be adapted for use with lines and filters having various cut-oil frequencies by making the compensating reactance variable, to provide for varying the frequency at which vthe resonance occurs. Moreover, the provision for adjusting the fr uency of resonance and the provision for a justin the degree of damping of the resonance a aptthe repeater for use with filters, characterized by considerably lower attenuations at freuencies well above the cut-off frequency t 'an in the neighborhood of the cut-ofl frequency, since t e resonance frequency may be made sufiiciently low, with respect to the cut-off frequency of the particular filter to be used, to insure that the repeater will not sing above the cut-ofi frequency and yet, be

1 plate cause of the low resonance frequency, in

spite of the damping of the resonance the repeater gain will be maintained high for the requencies below but in hood of the cut-ofi' frequency.

There is also associated with the transformer a second compensating reactanc'e, for resonating with thereactance presented by the primary winding of the transformer, to prevent this reactance s0 presented from unduly attenuating currents of low frequency, for instance,.frequencies in the nei hborhood of 1350 cles, and the degree 0 compensation so e ected, or the sharpness of this resonanceis determined by having the resistance mentioned above efiectively shuntedacross the second compensating reactance.

Fig. 1 of the ,drawin is a circuit diagram qf a repeater embo ying the invention; and Fig. 2 shows-curves for facilitating explanation of the invention.

In Fig. 1 an amplifier T is connected to repeat frome line Wto line E. Interposed between line W and the input electrodes of the amplifier is a potentiometer 1 and an innt transformer 2 having a primary windmg 3 and a secondary winding 4. Interposed between'the output electrodes of the amplifier and the line E is a filter 5 and an output transformer 6 having a primary winding 7. The filter, in the form shown, comprises coils 9-and 10 and condensers 21, 22 and23. The output transformer is of the usual three-windin type, and balancing networks NW and NE balance the impedances of lines W and E, respectively, in the usual fashion. Battery B supplies D. C. current for amplifier T through a choke coil 8, winding 7, and coils 9 and 10 of the filter. A condenser 11 by-passes A. G. around the battery and choke coil. The potentiometer 1 comprises a resistance, 12 having tap conductors 13 leading therefrom which may be selectively connected by means of adjustable contacts 14 to the primary winding 3. In order to make the impedance facmg the winding 3 thesame for all of the gain settings of the tentiometer, and therefore make the amping in the input circuit independent of the potentiometer setting resistances of suitably graduated values are embodied in the ta conductors, the resistances in series with e and tap conductors being substanthe neighbor- The filter used with the repeater may be any suitable filter adapting the repeater to whatever may be the degree of loading and the cut-off frequency of theparticular line in which the repeater is to be used.

However, in order to obtain. a sharp cutoff, it is frequently desirable to employ a filter of the suppression type, 'dueto G. A. Campbell and disclosed in British patent to Western Electric Company, Limited, No.

- 186,198. The filter 5 is a low pass filter of the type shown in Fig. of'that patent, and as explained in the patent, the use of such a filter renders it feasible to obtain a sharper cut-offthan if the filter employed were, for instance, of the type shown in Fig. 7 of U. S. patent to Campbell, No. 1,227,114, May 22, 1917, which is the type customarily employed in telephone repeaters of the general description of that of Fig. 1. Since the vacuum tube amplifier is 'a voltage operated device, transformer 2 is arranged to step up the voltage. It may, for example, have an impedance step up ratio. of 300 to 300,000 ohms. The input impedance of vacuum tube T with reference to direct current or low frequencies is usually of the order of infinity. and in any event ishigh relative to the impedance of the high winding of the transformen. At the higher frequencies of the voice range, however, the capacity between the tube electrodes, the capacity between the leads, and the capacity withinthe coil itself are appreciable. For these reasons the transformer presents an inductive reactance to the line in the lower part of the voice range and a capacity reactance in the upper part of the voice range. If no compensation for the effects of these reactances is provided, the repeater may give a desired gain in the middle portion of the frequency range, but the trans-- mission may fall 01f considerably at the upperand lower ends of the range, with resulting distortion of the speech si als. This would also result in poor transmlssion of ringing currents, which in practice frequency, as for exusually have a low ample, 135 cycles.

As disclosed in the applications of W. L. Casper, Serial No. 366,581, filed March 17, 1920, and Serial No. 462,883, filed April 20, 1921, an inductance 30 is rovided in series with primary "winding 3 aving such value that this inductance and the leakage inv ductance of the transformer will resonate with the capacity reactance above described at a frequency in the neighborhood of the are upper part of the voice frequency range;

and further, as disclosed in the application of Pa H.-Pierce, Serial No. 410,587, filed September 16, .1920, a condenser 31 is provided to annul the inductive reactance of l the transformer atfrequencies in the lower part of the voice range. 'As explained in the application of D. F. Whiting, Serial No. 406.861, filed August 30, 1920, it is frequently desirable to damp the resonance produced by condenser 31, so that the transmission-frequency characteristic of. the

transformer will not have a sharp peak or pronounced upward curve at the resonance frequency, and this damping may be ac-;

complished by shunting aresistance across the tuning capacity. Therefore, a resistance 32 is connected" in shunt relation to the capacity 31, the inductance 30 presenting negligibly ,low impedance at'the frequency at which condenser 31 tunes with the inductive reactance of the transformer.

The inductance 30 is provided with tap conductors 33 for engagement with an adjustable contact 34, whereby the amount of the inductance 30 connected in circuit may be varied; and an adjustable contact 35is provided, whereby the resistance 32 may be connected in shunt relation to any desired part of inductance 30, the capacity 31 presenting negligibly ldw impedance at the frequency at which inductance 30 resonates "with the transformer and tube capacities.

The value of the resistance 32 determines the degree of damping that this resistance exerts. upon the'low frequency resonance or resonance of capacity 31 with the inductive reactance of the transformer; but the degree of damping that the resistance 32 exerts upon the high frequency resonance, or resonance produced by inductance 30, depends not only on the value of resistance 32 but also on which of the tap conductors 33 is engaged by contact 35, the inductance 30 acting as an autotransformer feeding resistance 32 as a load. Thus, the degree of damping of the high frequency resonan e .can'be adjusted substantially independently of the degree to which the low frequency resonance is damped. Thelarger the ratioof output voltage to imput voltage of the.

auto-transformer 30 the greater will bethe damping effect of resistance 32 upon the high frequency resonance.

or re eating from line E to line W there I is provi ed an amplifier 'I" and auxiliary apparatus like that described above in connection with amplifier T, the reference characters used to designate corresponding parts of the auxiliary a paratus being the same in the case of ampli er T and the am lifier T, except that in the latter case the c aracters rimed. Fig. 2 shows gain frequency curves of the repeater. Curve A is for the repeater without the filter or the tuning circuit 30, 31,

32; curve B is for the repeater with the filter but without the tuning circuit; Curve C is for the repeater with the tuning (and damping) but Without the filter; and curve D is for the repeater with'both the filter and the tuning (and damping) circuit.

The filter 5 being ofv the suppression type shown in Fig. 1, the curve 'B rises, as-indicated at 28, at frequencies above the cut-off frequency of the filter, and therefore the repeater may tend to sing at these frequencies since the impedance unbalance between the lines and their balancing networks is likely. to be greater at frequencies considerably above the cutoff frequency than at frequencies below the cut-off frequency.

To reduce this tendency of the repeater to sing, the amount of inductance 30 connected in circuit is preferably so adjusted that the high frequency resonance point or frequency of the resonance produced by inductance 30 will fall below the frequency at which the hump .28 is highest adjusted that the higlf'frequency resonance point will fall betwen the cut-off frequency of the filter and the" higher part of the hump 28) in order to insure that the gain of the repeater without the filter will not be at its maximum where the filter attenuation above the cut-off frequency reaches a minimum or where the gain of the repeater and filter without the tuning circuit reaches'a maximum, above the cut-off frequency. For 35 example, referring to Fig. 2, the maximum gain shown by curve C occurs at about 2600 cycles, a point at which the filter attenuation is considerable and at which the impedance unbalance between, the lines and their balancing networks is not likely to be great;

indicated at thecrest of thehump 28.

Further, the contact 35 is so adjusted that I the damping of the high frequency resov with uniform transmission up to the cut-off:

nance is sufliciently great to insure that throughout whatever frequency range may be common to the humps 37 and 28 the repeater will not sing.

Within the limits imposed by these-adjustments to prevent singing, the frequency of the resonance produced by the inductance 30 and the degree of dampingof this resov nance are so adjusted with regard to whatever types of line and filter are being used,

asto compensate for variation of line and filter attenuation with frequency over the upper part of the frequency range to be transmitted so that a sharp cut-off effect,

point, is obtained. For example, it will be noted that the rise of curve C with ;fre-\ (and preferably is so I quency, over the upper part of the frequency range to be transmitted, is more than suflicient to compensate for change of filter attenuation over this part of this frequency range, the excess being for the purpose of taining the requisite degree of rise in curve C even though the damping of the resonance be high.

Although the invention has been described above with especial reference to the transmission of currents in the voice frequency 'range, it is not restricted to transmission of such frequencies, for its principles are apphcable also to the transmission of currents of other frequencies. It may be realized in various embodiments within .the scope of the appended claims.

What is claimed is:

1. In combination, a transformer having across its out ut terminals, an impedancesubstantially infinite at a given frequency,

a condenser forming with the inductance of said transformer a series tuned circuit at said frequency, an inductance, said condenser and one portion of said last men tioned inductance being serially related to each other with a resistance connected in substantially infinite at a given frequency,

a condenser forming with the inductance of said transformer a series tuned circuit at said frequency, an inductance, said .condenser and one portion of said last mentioned inductance bein serially related to each other with a resistance connected in shunting relation to said condenser and a different portion of said last'mentioned indifferent portion of said coil.

in shunting relation to said capacity and a 5. In combination, an electro'ntube' repeater having input electrodes, a transformer having output terminals connected in series with the space between said electrodes, a capacitive reactance forming with the induc tive reactance presented by the input terminals of said transformer a series tuned circuit at a frequency to be repeated, and an inductance, said-capacitive reactance and one portion of said inductance being serially reated to each with a resistance connected in shunting relation to a different portion of said inductance.

6. In combination, an electron tube having input electrodes, a transformer having output terminals connected in series with the space between said electrodes, the input ter- 'minals of said transformer presenting an inductive reactance at a frequency in the lower part of the voice range, a condenser connected in series with the input terminals of said transformer, said condenser being of such capacity as to tune with said inductive reactance at said frequency in the lower part of the voice range, and aninductance,-said condenser and one portion of said inductance being serially related to each other with a reslstance connected in shunting relation to a diflerent portion of said inductance.

7. In combination, a transformer having input terminals presentingan inductive reactance at low frequenqies and a capacitive reactance at relatively high frequencies, a condenser forming with said inductive reactanoe a circuit tuned toa relatively low frequency, an inductance having a portion form- 'ing with sa1d capacltive reactance a circuit tuned to a relatively high frequency, and a resistance connected in shunting relation to said condenser and a portion of'said coil.

8. In combination, an electron tube having input electrodes, a transformer having output terminals connected td said electrodes, acondenser'forming with the-induct ance presented by the input'terminals ofv said transformer a series tune circuit, an lnductance havlng a port1on serially related to sald condenser with a reslstance connected in shunting relation tosaid condenser and a portion of said last mentioned inductance, the first mentioned portion of said last mentioned inductance forming with the capacity between the transformer winding turns and 7 between said electrodes a circuit which is .resonant at a frequency for which the impedance of said condenser is negligibly low. '9. Inrombination, an electron tube having input electrodes, a transformer having I output terminals connected said elec "trodes, a condenser forming with the inductance presented by the input terminals of said transforn'ier a series tuned circuit, and a retard coil having a portion forming with the' capacity bewteen the transformer wind- ,ing turns and between said electrodes a circuit which is resonant at a frequency for which the impedance of said condenser is negligibly low, said portion. of said retard coil being serially related to said condenser, with a resistance connected'in shunting relation to said condenser and an adjustable portion of said retard coil whereby the degree of damping of the last mentioned resonance' may be adjusted substantially independently of the degree of damping of the first mentioned tuning.

- .10. In combination with a transfornier presenting in its primary circuit an inductive reactance at low frequencies and a capacitive reaclance at relatively high frequen cies, means for resonating with said inductive reactance, means for resonating with said capacitive reactance, and a resistance for damping said first mentioned resonance and adjustably connected to said second mentioned means for varying the degree of "practically infinite attenuation per section at a finite frequencyabove the cut-off frequency, and the gain frequency characteristlc of said amplifier-and filter having a maximum point at a finite frequency above the cut-off frequency, of an input transforme rifor said amplifier,-having inductance effectively inseries with one of its windings, said inductance being of such value as to resonate with the effective capacity presented by said transformer and the effective input capacity of said tube at'a frequency below the frequency of said maximum point above the'cut-ofi' fr uency. 1 In witness whereof, we hereunto subscribe our names thisj27th day of April, A. D., 1923.- I r r a DONALD A. QUARLES. FRANKLIN MOHR.

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