US2037107A - Transmission gain control - Google Patents

Transmission gain control Download PDF

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Publication number
US2037107A
US2037107A US758524A US75852434A US2037107A US 2037107 A US2037107 A US 2037107A US 758524 A US758524 A US 758524A US 75852434 A US75852434 A US 75852434A US 2037107 A US2037107 A US 2037107A
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frequency
current
line
relay
cycle
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US758524A
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Abraham Leonard Gladstone
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AT&T Corp
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American Telephone and Telegraph Co Inc
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B3/00Line transmission systems
    • H04B3/02Details
    • H04B3/04Control of transmission; Equalising
    • H04B3/10Control of transmission; Equalising by pilot signal

Definitions

  • This invention relates to devices for. controlling the over-all transmission loss in a communication transmission line, and more particularly to lines in which a pilot current is transmitted over a transmission line and its intensity or its energy level on reception is used as a measure of the net loss in the line.
  • This pilot signal is Ithen used to bring about adjustments to keep vthe over-all net loss at a substantially constant desired value.
  • the pilot signal has been a sustained frequency outside but near the speech frequency band or other signal band to be transmitted.
  • the pilot signal has been a tone within the message frequency band which is sent only intermittently and at moments not interfering with the message signal.
  • the necessary equipment has been spoken of as a tonlar, an abbreviation of tone operated net loss adjusting receiver.
  • the first of these has the advantage of being on continuously but has the disadvantage that its frequency is outside the signaling band to ⁇ be transmitted. Since the variations of the line characteristics at that frequency are not the same as the changes in frequency characteristics within the signaling band, there is imperfect regulation.
  • the advantage of the second type is that it makes adjustment for a typical frequency Within the signaling band but it has the disadvantage that the circuit Varies between adjustments and it may do so suificiently to remove considerable of the advantage of the tonlar unless adjustments are made quite frequently.
  • the purpose of this invention is to combine the advantages of the two types of tonlars, that is, to obtain, continuously, substantially correct compensation for variations at some selected frequency within the signaling band. I accomplish this by sending continuously a frequency just outside the signal band which supervises the line for that frequency but the apparatus for which is itself adjusted or calibrated from time to time by an occasional signal of frequency in the transmitted signal band in such manner vthat the correction is really in terms of the latter. Thus the variations that occur frequently at both of these pilot frequencies are eliminated and the slow change in the transmission characteristic between these two frequencies is compensated for before it becomes appreciable.
  • an incoming transmission line L with repeating coils and amplifiers there being two shown here.
  • the gain of these amplifiers may be controlled at least in part, by a suitably located potentiometer P1, here shown as on the input of the rst amplifier, and the vpotentiometer is controlled by a clutch mechanism #L operated by motor I2, to ⁇ raise or lower the contact of the potentiometer P14, thus controlling the net loss of the circuit in a manner hereinafter described.
  • the 3500 cycle current and occasional 1000 cycle current which come over the transmission line are taken off at the output of amplifier #2 and impressed on the input of amplifier #3 through an adjustable potentiometer P2.
  • the sensitivity of the relay R1 is controlled by a potentiometer P3 across the output of amplifier #3, and by changing the setting of this potentiometer, one controls the amount of 3500-cycles at the output of amplifier #2 which is required to operate the clutch mechanism #I in the one direction or the other.
  • the circuit functions on the 3500-cycle current in the same manner except that the 1000-cycle current may bring about a change in the setting of the potentiometer P3 for the purpose of adjusting or calibrating" the 3500-cycle circuit to cause the relay R1 to operate about that average value of the 3500-cycle current which is appropriate in View ofthe existing transmission loss at 1000 cycles.
  • the 1000- cycle current is picked olf by an amplifier-detector I8, tuned to 1000 cycles. It thus operates or releases the relay Rz, depending upon its strength, and so causes the clutch mechanism #2 to adjust the potentiometer P3, which in turn results in a corresponding adjustment in P1' until the desired amount of G-cycle current is obtained at the output of amplifier #2.
  • apulse-clipping circuit operates to remove the ground from the tongue of relay R2 and prevents any further change in P3.
  • This pulse-clipping circuit operates as follows: n
  • a relay R3 is connected in the outpit 'of the amplifier-detector I8 in parallel to relay R2. Controlled by the contact of relay R3 are two other relays, R4 and R5, Athese being in parallel with each other and effective on the making of R3.
  • the -relays R4 and R5 are both sensitive but R5 is a slow-'operate relay, rendered so by resistances 2U and grounded condenser 2
  • R3 When current due to the 100G-cycle is present in the output of detector I8, R3 operates 'and in turn brings about the operation of 'R4 and R5.
  • the operation of R4 applies ground Vto the tonguev of R2.
  • a short time later R5 operates to 'short-circuit R4, which in turn releases and the ground is removed from the tongue of R2.
  • relays R3 and then R5 release the tongue of R2 is left ungrounded and ⁇ the cycle is ready to be repeated. It is desirable, of course, that the relay R3 lshall not be responsive to any 100G-cyclev oscillations coming from the speech message itself. This is accomplished, in practice, by arranging that the amplitude of the intermittent 10004cycle control current shall be of a magnitude corresponding to testing conditions, that is, of a magnitude which should, in general, be large compared to any 1000 cycle not arising in connection with the speech message.
  • relay R3 In order furthenhowever, to preclude operation of this relay Rs by speech, it is desirable to make the relay R3 a slow-operate and quick-release relay, in which case, it will not be 4operated except by the definite intermittent M500-'cycle control current.
  • a system for maintaining substantially constant transmission loss over ay transmission line comprising a source of sustained current of one frequency and arsource of intermittent current of another frequency, each transmitted over the line as pilot currents, means responsive to the sustained current to kadjust the gain in accordance with the Vnet loss at that frequency, and means responsive tothe intermittent current to adjust the sensitivity of the first-named means in accordance with the net loss at frequency of the intermittent current.
  • the methodf of adjusting tandem repeaters for gain in a line comprising those repeaters', which consists in sending a continuous current of one frequency and an intermittent current of another frequency over the line, using the first current to adjust the gain of the repeaters in accordance with line variations at that frequency, and using the second current to control the effectiveness of the first in accordance with line variations at that second frequency.
  • the method of adjusting tandem repeaters for gain in a telephone line comprising those repeaters, which consists in sending over the line a continuous current of a frequency outside the signal frequency band and an intermittent current of a different frequency within the signal band, using the rst current to adjust the gain of the repeaters in accordance with line variations at that frequency, and using the second currentV to control the effectiveness of the first in accordance with line variations in the speech band.
  • a transmission line repeat'- ers therein, means for sending 'oversaid line a sustained tone frequency current, means for sending over said' line a second intermittent tone frequency current', means for separating out and detecting the'S'efrequenCiesfOr transmission into derived circuits, and means in' said 'derived 'cir'- cuits for adjusting the' gain -or loss of the line in accordance with line variations at the first frequency', and further means for controlling the adjustment by the' rst adjusting means in ac cordanc'e with line'variati'ons at the second fre;-
  • a telephone line having 'a repeater station thereon meansV controlled 'by aV tone having a frequency outside the'voice frequency range and transmitted Vcontinuously over the line for con'- trolling the gainto hold thev energy level beyond the repeater and at that frequency vwithin 'desir'ed limits, and additional means controlledV by a tone having a frequency within the voice fre-'- quency range transmitted' at intervals over the line'for controlling the effectiveness of the firstnanied control nieans in accordance with line variationsat'th frequency of the intermittent tone.
  • control means by currents transmitted diirng the intervals betweenthe transmission ⁇ of the intermittent frequency tone.

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Interface Circuits In Exchanges (AREA)

Description

M, w35 L. G. ABRAHAM TRANSMISSION GAIN CONTROL Filed Dec. 20, 1954 lli Patented Apr. 14, 1936 UNITED STATES TRANSMISSION GAIN CONTROL Leonard Gladstone Abraham, Madison, N. J., as-
signor to American Telephone and Telegraph Company, a corporation of New York Application December 20, 1934, Serial No. 758,524
9 Claims.
This invention relates to devices for. controlling the over-all transmission loss in a communication transmission line, and more particularly to lines in which a pilot current is transmitted over a transmission line and its intensity or its energy level on reception is used as a measure of the net loss in the line. This pilot signal is Ithen used to bring about adjustments to keep vthe over-all net loss at a substantially constant desired value.`
In certain cases where devices of this nature have been used, the pilot signal has been a sustained frequency outside but near the speech frequency band or other signal band to be transmitted. In other cases the pilot signal has been a tone within the message frequency band which is sent only intermittently and at moments not interfering with the message signal. In both cases the necessary equipment has been spoken of as a tonlar, an abbreviation of tone operated net loss adjusting receiver.
The first of these has the advantage of being on continuously but has the disadvantage that its frequency is outside the signaling band to` be transmitted. Since the variations of the line characteristics at that frequency are not the same as the changes in frequency characteristics within the signaling band, there is imperfect regulation. The advantage of the second type is that it makes adjustment for a typical frequency Within the signaling band but it has the disadvantage that the circuit Varies between adjustments and it may do so suificiently to remove considerable of the advantage of the tonlar unless adjustments are made quite frequently.
The purpose of this invention is to combine the advantages of the two types of tonlars, that is, to obtain, continuously, substantially correct compensation for variations at some selected frequency within the signaling band. I accomplish this by sending continuously a frequency just outside the signal band which supervises the line for that frequency but the apparatus for which is itself adjusted or calibrated from time to time by an occasional signal of frequency in the transmitted signal band in such manner vthat the correction is really in terms of the latter. Thus the variations that occur frequently at both of these pilot frequencies are eliminated and the slow change in the transmission characteristic between these two frequencies is compensated for before it becomes appreciable.
The invention will be better understood by reference to the following specification and the accompanying drawing, in which the ligure gives the essential circuit arrangement for a tonlar possessing the characteristics which I desire.
To make the description more definite and to give an example of the frequencies involved, it will be assumed that a speech signal is to be transmitted using the band of frequencies up to 3400 cycles. 'Ihen for the continuous control frequency we may take 3500 cycles, and for the intermittent frequency we may take 1000 cycles. It is to be understood, however, that these frequencies are given for illustrative purposes only and are not intended in any way to limit the scope of the invention.
Referring to the figure, there is shown an incoming transmission line L with repeating coils and amplifiers, there being two shown here. The gain of these amplifiers may be controlled at least in part, by a suitably located potentiometer P1, here shown as on the input of the rst amplifier, and the vpotentiometer is controlled by a clutch mechanism #L operated by motor I2, to` raise or lower the contact of the potentiometer P14, thus controlling the net loss of the circuit in a manner hereinafter described. The 3500 cycle current and occasional 1000 cycle current which come over the transmission line are taken off at the output of amplifier #2 and impressed on the input of amplifier #3 through an adjustable potentiometer P2. When 3500-cycle current alone is on the line it passes through an amplifier-detector I5, tuned to 3500 cycles, and then controls therelay R1. If the current is too large, due to a decrease in transmission loss, the relay R1 operates, causing the lower gain clutch of mechanism #I to be actuated, thus changing the setting of P1 and restoring the 3500-cycle current at the terminal of amplifier #2 to ya value such that the tongue of relay R1 is restored to its normal intermediate position. If, on the other hand, the 3500-cycle current is too weak, the relay R1 closes on the back contact and the opposite effect is obtained, that is, the raise gain clutch of mechanism #I is actuated, thus again changing the setting of P1 to restore the 3500-cycle current at the output of amplifier #2 to its normal value. The sensitivity of the relay R1 is controlled by a potentiometer P3 across the output of amplifier #3, and by changing the setting of this potentiometer, one controls the amount of 3500-cycles at the output of amplifier #2 which is required to operate the clutch mechanism #I in the one direction or the other. When the occasional 1000-cycle current is added, the circuit functions on the 3500-cycle current in the same manner except that the 1000-cycle current may bring about a change in the setting of the potentiometer P3 for the purpose of adjusting or calibrating" the 3500-cycle circuit to cause the relay R1 to operate about that average value of the 3500-cycle current which is appropriate in View ofthe existing transmission loss at 1000 cycles.
More specifically, it will be seen that the 1000- cycle current is picked olf by an amplifier-detector I8, tuned to 1000 cycles. It thus operates or releases the relay Rz, depending upon its strength, and so causes the clutch mechanism #2 to adjust the potentiometer P3, which in turn results in a corresponding adjustment in P1' until the desired amount of G-cycle current is obtained at the output of amplifier #2.
After a suiiicient time interval to insure that this adjustment has been made (and this will be in the order of half a second), apulse-clipping circuit operates to remove the ground from the tongue of relay R2 and prevents any further change in P3. This pulse-clipping circuit operates as follows: n
A relay R3 is connected in the outpit 'of the amplifier-detector I8 in parallel to relay R2. Controlled by the contact of relay R3 are two other relays, R4 and R5, Athese being in parallel with each other and effective on the making of R3. The -relays R4 and R5 are both sensitive but R5 is a slow-'operate relay, rendered so by resistances 2U and grounded condenser 2|. When current due to the 100G-cycle is present in the output of detector I8, R3 operates 'and in turn brings about the operation of 'R4 and R5. The operation of R4 applies ground Vto the tonguev of R2. A short time later R5 operates to 'short-circuit R4, which in turn releases and the ground is removed from the tongue of R2. When the 100`Ucycle current is removed (and it is on for a short time only), relays R3 and then R5 release, the tongue of R2 is left ungrounded and` the cycle is ready to be repeated. It is desirable, of course, that the relay R3 lshall not be responsive to any 100G-cyclev oscillations coming from the speech message itself. This is accomplished, in practice, by arranging that the amplitude of the intermittent 10004cycle control current shall be of a magnitude corresponding to testing conditions, that is, of a magnitude which should, in general, be large compared to any 1000 cycle not arising in connection with the speech message. In order furthenhowever, to preclude operation of this relay Rs by speech, it is desirable to make the relay R3 a slow-operate and quick-release relay, in which case, it will not be 4operated except by the definite intermittent M500-'cycle control current.
rIt is apparent that many variations may be made in the combination of relays to bring about the desired.` results, all withoutL departing from the spirit of this invention. This is particularly true of the pulse-clipping circuit,` andthe particular arrangement shown is for illustrative purposesonly.
What is claimed is: Y. Y
l. In a system for maintaining substantially constant transmission loss over ay transmission line, comprising a source of sustained current of one frequency and arsource of intermittent current of another frequency, each transmitted over the line as pilot currents, means responsive to the sustained current to kadjust the gain in accordance with the Vnet loss at that frequency, and means responsive tothe intermittent current to adjust the sensitivity of the first-named means in accordance with the net loss at frequency of the intermittent current.
2. The methodf of adjusting tandem repeaters for gain in a line comprising those repeaters', which consists in sending a continuous current of one frequency and an intermittent current of another frequency over the line, using the first current to adjust the gain of the repeaters in accordance with line variations at that frequency, and using the second current to control the effectiveness of the first in accordance with line variations at that second frequency.
3. The method of adjusting tandem repeaters for gain in a telephone line comprising those repeaters, which consists in sending over the line a continuous current of a frequency outside the signal frequency band and an intermittent current of a different frequency within the signal band, using the rst current to adjust the gain of the repeaters in accordance with line variations at that frequency, and using the second currentV to control the effectiveness of the first in accordance with line variations in the speech band.'
4; Themethod of adjusting the transmission level in a line which consists in sending a con; tinuous tone frequency current andan intermittent tone frequency current over the line, selec'- tively separating these from the line where the adjustment is to'be made, detecting these'currents and applying the first current to introduce gain 'or 'loss in accordance with the intensity of the current of that frequency as detected, and applyingthe lsecond current to calibrate and control the adjustments of 'the rst in accordance withline'variations at the second frequency.
5. `In combination, a transmission line, repeat'- ers therein, means for sending 'oversaid line a sustained tone frequency current, means for sending over said' line a second intermittent tone frequency current', means for separating out and detecting the'S'efrequenCiesfOr transmission into derived circuits, and means in' said 'derived 'cir'- cuits for adjusting the' gain -or loss of the line in accordance with line variations at the first frequency', and further means for controlling the adjustment by the' rst adjusting means in ac cordanc'e with line'variati'ons at the second fre;-
quen'cy.'
6. A telephone line having 'a repeater station thereon, meansV controlled 'by aV tone having a frequency outside the'voice frequency range and transmitted Vcontinuously over the line for con'- trolling the gainto hold thev energy level beyond the repeater and at that frequency vwithin 'desir'ed limits, and additional means controlledV by a tone having a frequency within the voice fre-'- quency range transmitted' at intervals over the line'for controlling the effectiveness of the firstnanied control nieans in accordance with line variationsat'th frequency of the intermittent tone.
'1. The Combination of claim ceharacterized by means for 'preventing opeationof the second= named control means by currents transmitted diirng the intervals betweenthe transmission `of the intermittent frequency tone.'
8.` The combination of 'claim`6 characterized by means comprising a slow-'actingirelay'for preventing operation 'ofthe secondnamed'control means by Voice currents during communication over 'the line.
9. The combination of claim 6characterl'zed by the fact that there is a sloW-acting'relay under control ofv detected intermittent frequency which'relay prevents operation of the secondnamed 'control 'means by voice 'currents 'during communication over'tlie line.
LEONARD `ca '.ADs'roNn ABRAHAM.
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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2626993A (en) * 1939-01-10 1953-01-27 Int Standard Electric Corp Control of carrier transmission systems by pilot frequencies
US2913668A (en) * 1956-10-30 1959-11-17 Edward N Lide Ratio voltmeter
US3048817A (en) * 1958-01-16 1962-08-07 Phillips Petroleum Co Gain control amplifier
US3483334A (en) * 1964-09-16 1969-12-09 Philips Corp Communication system with gain controlled intermediate repeater stations
US3942137A (en) * 1973-11-28 1976-03-02 Compagnie Industrielle Des Telecommunications Cit-Alcatel Device for the remote adjustment of an inaccessible element

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2626993A (en) * 1939-01-10 1953-01-27 Int Standard Electric Corp Control of carrier transmission systems by pilot frequencies
US2913668A (en) * 1956-10-30 1959-11-17 Edward N Lide Ratio voltmeter
US3048817A (en) * 1958-01-16 1962-08-07 Phillips Petroleum Co Gain control amplifier
US3483334A (en) * 1964-09-16 1969-12-09 Philips Corp Communication system with gain controlled intermediate repeater stations
US3942137A (en) * 1973-11-28 1976-03-02 Compagnie Industrielle Des Telecommunications Cit-Alcatel Device for the remote adjustment of an inaccessible element

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