US2066332A - Carrier wave transmission system - Google Patents

Carrier wave transmission system Download PDF

Info

Publication number
US2066332A
US2066332A US757421A US75742134A US2066332A US 2066332 A US2066332 A US 2066332A US 757421 A US757421 A US 757421A US 75742134 A US75742134 A US 75742134A US 2066332 A US2066332 A US 2066332A
Authority
US
United States
Prior art keywords
circuit
carrier
waves
amplifier
line
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US757421A
Other languages
English (en)
Inventor
Robert S Caruthers
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
AT&T Corp
Original Assignee
Bell Telephone Laboratories Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority to NL42193D priority Critical patent/NL42193C/xx
Application filed by Bell Telephone Laboratories Inc filed Critical Bell Telephone Laboratories Inc
Priority to US757421A priority patent/US2066332A/en
Application granted granted Critical
Publication of US2066332A publication Critical patent/US2066332A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04JMULTIPLEX COMMUNICATION
    • H04J1/00Frequency-division multiplex systems
    • H04J1/02Details
    • H04J1/06Arrangements for supplying the carrier waves ; Arrangements for supplying synchronisation signals
    • H04J1/065Synchronisation of carrier sources at the receiving station with the carrier source at the transmitting station
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04JMULTIPLEX COMMUNICATION
    • H04J1/00Frequency-division multiplex systems
    • H04J1/02Details
    • H04J1/06Arrangements for supplying the carrier waves ; Arrangements for supplying synchronisation signals
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04JMULTIPLEX COMMUNICATION
    • H04J1/00Frequency-division multiplex systems
    • H04J1/02Details
    • H04J1/08Arrangements for combining channels
    • H04J1/085Terminal station; Combined modulator and demodulator circuits

Definitions

  • This invention relates to carrier line transmission of speech or'other signals. It has particular reference to the transmission of modulated carrier current waves of the same frequency range or voice filter on one side of the modulator-demodulator and a high-pass or other high fre-' quency filter on the other side. It is practicable go to design these filters to present an impedance across the line at a point betweenthem approaching a constant resistance at all frequencies, the degree of approach depending on how accurately the impedances and other quantities involved 25 satisfy-the mathematical relations applicable to the problem.
  • a bridge 35 or hybrid coil balance is obtained between the impedance presented at the common terminals of these channel filters and a balancing resistance, the mutually conjugate terminals of the hybrid coil being joined by a circuit including a bilateral 40 modulator-demodulator and an amplifier.
  • This type of terminal two-way amplifier-modulator-demodulator is especially advantageous in a system of the type disclosed and claimed in U. S. patent to H. S. Black, No. 1,983,528, granted 45 December 11, 1934, in which a source of carrier waves is supplied at one terminal only of the system.
  • An advantage of that system is that the opposite terminal needs no attention for long periods of time, so that maintenance is confined practically to the station at which the carrier source is located.
  • the amplification that is in- .troduced in accordance with this invention is also accomplished by provision of the amplifier at only 5 the attended station.
  • the invention is not limited,
  • a further feature of the invention comprises the use of an amplifier for both amplifying the transmitted and received waves and generating 5 carrier waves for the system. This is made possible, by the invention, by using an element or device having non-linear resistance to limit the amplitude of the generated oscillations to a value below the overload point of the amplifier whereby the load carrying capacity of the amplifier is divided between the two functions of amplification and oscillation production.
  • This feature of my invention is broadly disclosed and claimed in my application for U. S. patent Serial No. 757,422 filed of even date herewith.
  • a feature to be claimed in the present application and closely related to the last mentioned feature comprises a combination amplifier and oscillation generator in which the non-linear resistance referred to is-furnished by the modulator or demodulator of a carrier system.
  • This application contains subject-matter transferred from my said application Serial ,No. 757,422.
  • Fig. 1 is a schematic circuit diagram of a single channel carrier and voice channel system embodying the invention
  • Fig. 1A shows a detail modification applicable to the circuit of Fig. 1;
  • Fig. 2 shows curves indicating thebalance requirements of the terminal circuit of Fig. 1 under given conditions
  • Fig. 3 shows a modified type of circuit for gen- 40 crating the carrier waves and amplifying according to the invention
  • Fig. 3A shows a detail modification
  • Figs. 4 and 5 show the application of wave amplifying and generating circuits to carrier systems according to the invention. Except for the provisions for introducing amplification the circuit of Fig. 1 may be considered the same as that shown more in detail in the above noted patent of H. S. Black, the correspond- 60 ing parts being similarly numbered in the two drawings. I
  • the main line L is arranged to carry a direct voice transmission and another transmission at carrier frequency, the terminal points of the voice channel being indicated at jacks II and the voice frequency terminals of the carrier channel being shown at 3
  • Low-pass filters III, II) and high-pass filters 34, 34' serve to separate the voice and carrier transmissions to their respective circuits.
  • the carrier terminal at the left of the figure comprises low-pass filter 32 and high-pass filter 34, a modern unit 33 serving both as modulator and demodulator, a carrier source 40, such as a 7 Vacuum tube oscillator, a hybrid or bridge connection 20 and balancing resistance 2
  • This circuit may also include a filter 23 to be referred to later.
  • the carrier terminal at the right of the figure comprises in addition to the high-pass filter 34", the modem unit 33' and the low-pass filter 32'.
  • pass through lowpass filter 32 and into the branch at point l5 lead.- ing to bridge circuit 20. They are thence impressed on the modulator-demodulator 33 where they combine with carrier currents from source 40 to produce sideband waves.
  • These sideband waves and the unmodulated carrier are amplified at 22 and pass through filter'23 to the bridge cir cuit terminals opposite to those to which modem 33 is connected, and thence across terminals l5, through high-pass filter 34 and out on line L.
  • are impressed on the low frequency terminals of modulator-demodulator 33' after passing filter 32'.
  • Carrier waves generated at 40 are also continuously present at the high frequency terminals of this modulatordemodulator 33' by virtue of the path just traced over line L for' carrier and sidebands.
  • the carrier and voice intermodulate to produce sideband waves which traverse line L to the station at the left where they are selectively transmitted through highpass filter 34 and into the branch at l5 leading to the bridge connection 20. Thence they are impressed on the modulator-demodulator circuit 33 in which they interact with carrier waves from source 40 and produce voice waves. These are amplified at 22 and passed by filter 23 to the output-bridge terminals and thence through low-pass filter 32 out into the connected voice line at 3
  • the modulator-demodulator 33 is a double balanced circuit by which is meant that its input terminals for speech, car-v its opfilters as" ordinarily designed and employed present an impedance at this point which approximates a constant resistance at all frequencies.
  • Hybrid coil 20 may therefore be balanced by using a simple resistance 2
  • filters 32 and 34 may not have the same cut-ofi frequency or overlapping pass ranges, in
  • Filter 23 in that case may be a suppression type filter preventing the circulation of frequencies around the amplifier loop within the range over which the circuit has insufficient balance.
  • the line equivalent is of the order of 10 decibels and only such a degree of amplification is required as will reduce the equivalent to some value less than 10 decibels. For example, a gain which will produce a reduction of 6 decibels in transmission equivalent is all that may be needed in a practical case.
  • the curves in Fig. 2 show that the balance requirements in such a case are well within the limits that can be readily met in a typical or ordinary system without resort to special refinements-of filter or circuit design.
  • the curves of Fig. 2 are calculated curves showing the relation between the gain that is effective in reducing the assumed .10 decibel line equivalent and the required balance at point assuming in the case of curve A a 6 decibel echo requirement at jack 3
  • the hybrid coil circuit of Fig. 1A may be used by direct substitution of the rectangle 23 and contents of Fig. 1A for that of Fig.1. Choke coil 23' may be necessary or desirable in this case in order to afford a path for direct current resulting from rectification by the modem 33 of carrier from source 43.
  • a portion of a terminal the-modem unit isindicated'at 33.
  • an oscillator such as 43 of Fig.
  • Applicant is enabled to accomplish the two functions of generation and amplification in this circuit by employing a non-linear element indicated at 41, which exhibits an overload characteristic for the oscillations being generated, well below the overload point of the tube 46, thus leaving a useful load carrying margin to enable the tube to amplify speech and sideband currents.
  • Element 41 may be a, resistance material known as Thyrite comprising silicon carbide crystals and a binder as disclosed in U. S. Patent 1,822,742 to McEachron, September 8, 1931, or any other suitable non-linear resistance device.
  • the tube 46 has an input transformer 56 and an. output transformer 5
  • Tube 46 is shown as a pentode having a grid bias resistor 48 through which the steady space current flows.
  • a feed-backpath 52 is provided from the secondary side of output coil 5
  • the frequency of the generated oscillations is determined by .the parallel resonant shunt path 53, which preferably has a very high ratio of reactance to resistance so as to discriminate against the feeding back of any except carrier frequency waves.
  • Resistances 54 and 55 are connected in the feedback path on either side of the 'I'hyrite element and anti-resonant circuit as shown.
  • waves of the carrier frequency are built up in the usual manner until the loss around the closed loop equals the gain.
  • resistors 54, 55 the amplitude of the oscillations flowing in the feedback path may be controlled, these resistors being preferably variable and adjusted to the values to give the desired ratio of oscillations transmitted through output coil 5
  • the loss in the loop circuit is determined in part by the shunt overload element 41 which, as stated, has a non-linear resistance such as to cause the loss to increase rapidly as the amplitude exceeds a certain value.
  • Fig. 3A shows an alternative type of feed-back path 62 which may replace feed-back path 52 of Fig. 3.
  • the only difference is in the substitution of copper-oxide rectifiers as the overload element in place of Thyrite 47.
  • Two oppositely poled copper-oxide rectiflers 63 and 64 are used. These might be unbiased or biased by batteries but the preferred circuit is as shown comprising resistorcondenser combinations 65 and 66 in series with respective rectifiers whereby the direct current component of the rectified current produces a potential drop in the resistances for bias purposes, the alternating components being passed by the shunt condensers.
  • Thev operation of the circuit follows from the description given of Fig. 3, the copper-oxide rectifiers performing the load limiting function necessary to keep the oscillations below the load carrying limit 'of the amplifier 46.
  • the overload elements 41 and 63, 64 can be omitted if the modem unit 33 is designed to introduce into the amplifier-oscillation generating circuit an overloadcharacteristie at theproper amplitude of generated waves.
  • This overload or limiting action should, as previously described, occur at an amplitude correspondingto a value well below that at which the amplifier itself begins to limit the current so that an effective load-carrying capacity is left for the amplifier.
  • Fig. 4 indicates a terminal of a carrier telephone system comprising an eastward multip ex line 12 and a westward multiplex line 13.
  • -For the transmitting line I2 band filter 16 leads to a modulating circuit connected on the other side to low frequency line "in which may lead to an exchange where it is extended as a voice frequency line on either a four-wire or two-wire basis.
  • the westward or receiving line is shown with band filter 11 leading through resistance bridge network 8
  • voice line H which may lead to the same-point as voice line Hi.
  • the modulator 18 and the demodulator 19 are each shown as of. the bridge type employing nonlinear resistances which may be copper oxide rectifiers, for example.
  • the speech is applied across one diagonal of the bridge while the carrier used for modulating or demodulating purposes and, in
  • demodulator 19 the sideband, are applied across the opposite diagonal.
  • the receiving amplifier 90 is provided with a feed-back circuit comprising frequency-determining combination 26, 21 and the non-linear resistance element S (which may comprise element 41 or elements 63, 64 of the previousflgures) in a circuit similar to that of Fig. 4 of my copend ing application except that the bridge of that figure is omitted in this figure on the output side of the amplifier.
  • the amplifier 90 therefore, serves as an oscillation generator producing waves of .carrier frequency which are applied to the modulator l8 and the demodulator 19.
  • the bridge comprising ratio arms 80 and 8
  • the bridge is preferably adjusted so that the loss from the feed-back path into modulator I8 is low whereas the loss into the input of amplifier 90 is high. It is assumed that the same frequency carrier wave is used for a given channel on each line 12 and 13.
  • Speech waves coming from the speech line to which line 10 is connected pass through lowpass filter 14 and modulate in the modulator 18 the carrier wave supplied from the amplifier-oscillator circuit 90, 26, 21.
  • Modulator I8 is balanced so that the unmodulated carrier component is not transmitted.
  • a potentiometer is included between two of the copper oxide elements as shown, equipped with a slider to which one of the carrier input terminals is connected.
  • One sideband of the resulting modulated wave is transmitted from resistance network 83 through band-pass filter 16 into the outgoing line 12.
  • Resistance network 83 is a pad preventing transmission irregularities due to interaction of copper oxide and band filter rcactances.
  • waves from other lines similar to line 10 in other channels are used to modulate carrier waves of other frequencies and the resulting sideband frequencies are transmitted through other band filters to the same line 12.
  • a number of sideband modulated waves are produced and transmitted over the line 13 to the station shown on the drawings.
  • One of these sidebands passes through band filter TI and is impressed on the bridge circuit previously describedof which two of the arms are the resistances and 8
  • Some of the carrier wave generated in the circuit comprising amplifier 90 is impressed together with the sideband components on the demodulator 19.
  • the demodulated voice frequency components are then transmitted. through the low-pass filter I5 and impressed upon the voice frequency line 1
  • may be so proportioned that the loss from the output of band filter ll to the input of amplifier 90 is low whereas the loss from the band filter 17 into the modulator I9 is high.
  • the amplifier 90 may be made to perform the twofold function of generating oscillations and amplifying waves.
  • the nonlinear circuit 19 furnishes the overload characteristic for determining the maximum amplitude of. the oscillations generated in the circuit in the same manner as is described hereinbefore in connection with the element S. This represents a simplification.
  • Fig. 5 discloses a circuit generally similar to that of Fig. 4 but capable of greater accuracy in the frequency of the generated carrier wave.
  • the type of oscillator circuit disclosed is essen- 'tially that of Fig. 2 of my copending application,
  • a shunt type but it includes a crystal 9'! for ac curately determining the frequency of the waves generated. It also'makes use of the fact that the impedancesof coils II and I2 are fairly pure capacity rcactances at carrier frequencies on the sides facing the tube. Condenser l8 and coil 9
  • the space current circuit for the tube .90 may be traced from ground through battery I3, choke coil l9, primary output coil l2 to the anode of tube 9
  • the path that is traversed by speech waves is from anode through primary winding of output coil l2, condenser IM and resistance 94 to the cathode, so that resistance 94 represents a coupling from plate to grid circuit for speech waves, this coupling being of such sign as to reduce the degree of amplification for the speech waves.
  • the resistance 94 being variable offers a control for the gain of the amplifier tube 90 since variations in this resistance control the amount of voltage of Y voice frequency (as well as direct current) that is fed back reversely on the grid.
  • the leads I09 may be extended to a convenient point for mount; ing the control 94 along with similar controls 'for other receiving channels.
  • the copper oxide rectifiers in modulator 19 are so poled with respect to those in demodulator 19 that carrier waves applied to both modulator and demodulator from the coil 92 flow alternately through 18 and 19 in opposite half waves of the carrier.
  • This form of connection of the modulator and demodulator to the carrier supply circuit affords an impedance which is favorable to the suppression of second order harmonics from the carrier supply circuit.
  • modulators such as those employing copper oxide rectifiers the second har-.
  • Fig. 5 The operation of Fig. 5 is generally similar to that described in Fig. 4.
  • Speech waves in line 10 are transmitted through the modulating appa ratus and eventually into eastward carrier line I2 in the same manner as described in Fig. 4.
  • Modulated carrier waves received over line 13 from the opposite station pass through band filter l1 and are demodulated at 19.
  • the inductances 99 olfer high impedance to the sideband current in shunt of the modulator 19 but permit the passage of speech waves with low loss.
  • the resulting speech waves' are impressed on the amplifier .90 through input coll II and from the output Y of the amplifier 90 they pass through output coll l2, low-pass filter 15 into line II.
  • the gain of the amplifier 90 for the speech waves may be varied.
  • the tube 90 continually produces oscillations of the carrier frequency as determined by the crystal 91 and the carrier frequency waves are supplied to both the modulator I8 and demodulator I9.
  • the nonlinear impedance which limits the maximum amplitude of the generated carrier oscillations is that of modulator 18 or demodulator 19 which are effectively connected across 9
  • the maximum amplitude of the oscillations is limited to a point sufliciently below the overload point of amplifier 90 to permit the efilcient amplification v of the detected speech waves.
  • each transmitting channel at a station is paired with a corresponding receiving channel
  • the same carrier frequency wave is used for both channels and is produced in a common oscillating circuit as disclosed.
  • Oscillating circuits of identically the same carrier frequency are, of course, employed at the opposite terminal for each pair of channels.
  • a terminal circuit for a carrier current system a voicetcurrent line terminating in a voice-frequency filter, a high frequency circuit terminating in a carrier frequency filter, a circuit having terminals connected to receive currents from both of said filters and other terminals connected to transmit carrier and sideband currents into each of said filters, said circuit including a source of carrier waves, a modulator-demodulator and an amplifier, a balanced connection for associating said sets of terminals in mutually conjugate relation to each other, with said filters, said filters presenting to said balanced connection a substantially constant impedance branched froma point between said filters having a balanced impedance and mutually conjugate branches and a circuit connected to said branches including a source of carrier waves, a modulator demodulator and an amplifier.
  • a source of carrier waves at only one terminal of the line a bilateral modulator-demodulator at another station on the line for demodulating received waves and modulating carrier current received over said line by signals to be sent from that station, a local circuit at said one terminal having pairs of terminals connected in conjugate relation to each other and connected to the line for both transmitting to and receiving from the line, said source of carrier waves being connected to said local circuit, said local circuit including a modulator-demodulator and an amplifier, said amphfier amplifying the waves traversing the system in both directions.
  • a duplex signaling system comprising a high frequency transmission line connecting stations adapted for connection to subscribers lines, a modulator-detector device at each station connected between said transmission line and a subscribers line, each of. said devices serving as a modulator for signals passing from the respective subscriber's line to said high frequency transin energy transfer relation to said line but mutually conjugate to each other, and an amplifier in said loop circuit.
  • a combination amplifier-oscillation generator comprising a space discharge device having input, output and feed-back circuits, a modulatordemodulator, said device producing and supplying to said modulator-demodulator sustained oscillations to be modulated and demodulated, and amplifying the products of such modulation or demodulation, said feed-back circuit being effectively connected to an element having a limiting characteristic limiting the generated oscillations to an amplitude below the load-carrying limit of said device, thereby leaving a load-carrying margin for said device for amplification.
  • a two-way carrier terminal comprising a modulator-demodulator, an amplifier connected to said modulator-demodulator for amplifying 11.
  • a wave modulator an amboth transmitted and received signal waves
  • said amplifier having a feed-back circuit for causing the amplifier to generate carrier waves
  • circuit connections for supplying the waves so generated to said modulator-demodulator
  • said modulatordemodulator introducing a non-linear resistance into the amplifier-oscillation generating circuit and limiting the amplitude of the generated oscillations to a value below that corresponding to the effective load limit of said amplifier.
  • a wave modulator an amplifier, a source of modulating waves, circuit connections for causing said amplifier to generate oscillations and supply them to said modulator for modulation therein by said modulating waves, circuit connections for impressing wave products of such modulation on said amplifier for amplification, said modulator serving to limit the amplitude of the oscillations generated by said amplifier to a point below the overload point of the amplifier whereby said amplifier is enabled to amplify said wave products of modulation.
  • a wave moduiat ing means connected to amplify waves in a circuit in series with said modulating means, a feed-back circuit for said amplifier for enabling the amplifier to generate carrier oscillations, means to supply the oscillations to said modulating means for modulation therein by signal waves, and means to limit the amplitude of the generated oscillations to a value below that corresponding to the upper limit of the loadcarrying capacity of the amplifier.
  • a carrier wave system terminal comprising a transmitting channel including a modulator, and a receiving channel including a demodulator, said modulator and demodulator each being of the rectifying type, a demodulator amplifier connected in series relation with said demodulator in the receiving channel for amplifying received waves, a feed-back path forming with said amplifier a carrier wave generating system, means to supply the generated carrier waves to both said modulator and said demodulator, the circuit relations being such that the carrier wave is transmitted through the modulator and the demodulator alternately in successive half periods of the carrier wave, and means limiting the generated waves to a value sufilciently low to enable the amplifier to amplify received waves despite the use of the amplifier for simultaneously generating the carrier waves.

Landscapes

  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Amplifiers (AREA)
US757421A 1934-12-14 1934-12-14 Carrier wave transmission system Expired - Lifetime US2066332A (en)

Priority Applications (2)

Application Number Priority Date Filing Date Title
NL42193D NL42193C (enrdf_load_stackoverflow) 1934-12-14
US757421A US2066332A (en) 1934-12-14 1934-12-14 Carrier wave transmission system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US757421A US2066332A (en) 1934-12-14 1934-12-14 Carrier wave transmission system

Publications (1)

Publication Number Publication Date
US2066332A true US2066332A (en) 1937-01-05

Family

ID=25047751

Family Applications (1)

Application Number Title Priority Date Filing Date
US757421A Expired - Lifetime US2066332A (en) 1934-12-14 1934-12-14 Carrier wave transmission system

Country Status (2)

Country Link
US (1) US2066332A (enrdf_load_stackoverflow)
NL (1) NL42193C (enrdf_load_stackoverflow)

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3426271A (en) * 1964-08-14 1969-02-04 Pierre Alais Displacement measuring system with high frequency source and low frequency output terminal connected by coaxial cable to measurement and detection circuit
US4996709A (en) * 1988-05-12 1991-02-26 Tandy Corporation Intercom telephone

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3426271A (en) * 1964-08-14 1969-02-04 Pierre Alais Displacement measuring system with high frequency source and low frequency output terminal connected by coaxial cable to measurement and detection circuit
US4996709A (en) * 1988-05-12 1991-02-26 Tandy Corporation Intercom telephone

Also Published As

Publication number Publication date
NL42193C (enrdf_load_stackoverflow)

Similar Documents

Publication Publication Date Title
US2066333A (en) Wave amplification and generation
US2164383A (en) Magnetic device
US2282102A (en) Signaling
US2291369A (en) Polar carrier telegraph system
US2151464A (en) Restricted frequency transmission
US2148532A (en) Radio repeater
US2066332A (en) Carrier wave transmission system
US1673002A (en) Control of electric waves
US1941068A (en) Radiosignaling
US2104012A (en) Multiplex radio signaling system
US2299487A (en) Electric wave transmission system
US2644036A (en) Receiver for two-tone carrier systems
US2271078A (en) Modulating system
US2457013A (en) Angle modulated wave discriminator
US2315050A (en) Frequency modulation system
US2212240A (en) Carrier wave modulating system and apparatus
US1502811A (en) High-frequency multiplex signaling system
US2095327A (en) Phase modulation
US1763015A (en) Operation of electric space-discharge devices
US2657280A (en) Hydbrid circuits
US2218526A (en) Transmission of frequencymodulated waves
US1654902A (en) Modulating system
US1968528A (en) Communication system
US1638580A (en) Method of and means for transmitting signals
US1662966A (en) Substation circuit