US2182841A - Reduction of distortion in signal transmission systems - Google Patents

Reduction of distortion in signal transmission systems Download PDF

Info

Publication number
US2182841A
US2182841A US208790A US20879038A US2182841A US 2182841 A US2182841 A US 2182841A US 208790 A US208790 A US 208790A US 20879038 A US20879038 A US 20879038A US 2182841 A US2182841 A US 2182841A
Authority
US
United States
Prior art keywords
grid
tube
circuit
cathode
voltage
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
US208790A
Other languages
English (en)
Inventor
James R Davey
John L Hysko
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 BE434405D priority Critical patent/BE434405A/xx
Application filed by Bell Telephone Laboratories Inc filed Critical Bell Telephone Laboratories Inc
Priority to US208790A priority patent/US2182841A/en
Priority to FR854639D priority patent/FR854639A/fr
Application granted granted Critical
Publication of US2182841A publication Critical patent/US2182841A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L27/00Modulated-carrier systems
    • H04L27/02Amplitude-modulated carrier systems, e.g. using on-off keying; Single sideband or vestigial sideband modulation
    • H04L27/08Amplitude regulation arrangements

Definitions

  • Another object is to reduce signal distortion in a telegraph transmission system, including a type of distortion known as telegraph bias.
  • marking and spacing signals in transmission over a system are subject to distortion such that at the receiving end of thesystem the durations of the marking and spacing signals are different from those they had at the transmitting end of the system, and will vary from time to time.
  • This type of distortion commonly called telegraph bias, may be due to chang'es in repeating relay adjustments, battery voltages or received telegraph currents caused by changes in line equivalent.
  • this telegraph bias has been reduced by utilizing the received signal variations to control the bias on the control grid of a vacuum tube detector in the telegraph receiving circuit, to vary the gain of that circuit so as to compensate for the received level variations and thus prevent them from aiecting the operation of the receiving relay.
  • the above objects are attained in an improved design of voice-frequency carrier telegraph receiving circuit, the operation of which is practically independent of changes in vacuum tubes, receiving relays and battery voltages, and in which the signal distortion is negligible even at the lowest carrier frequencies.
  • a feature of this circuit is an easily adjustable level compensator circuit which will maintain substantially unbiased signal reception over a Wide range of amplitude levels of the received current, and which is practically free of any drift effects, that is, a circuit in which the compensating voltage is a function of the incoming level only, and not of the signal characters being received.
  • the circuit employs a suppressor grid of a multigrid vacuum tube controlling the operation of the receiving telegraph relay, to obtain a readily adjustable current for controlling the gain of one or more amplifying tubes in the circuit to obtain the 'desired compensation.
  • An auxiliary feature is the use of the multigrid vacuum tube to obtain a low resistance in the charging path of a condenser controlling the gain of the compensating vacuum tube, to enable it toA be'quickly charged during marking signals, and a high resistance in thev discharge path for the condenser during the spacing period, thus reducing the amount of drift, i. e., change in control voltage across the condenser due to the varying length of successive marking signal characters, and the resulting characteristic distortion.
  • Fig. l shows schematically a receiving circuit for a voice-frequency carrier telegraph system embodying the invention.
  • Fig. 2 is a curve illustrating the improved operation characteristic obtained in the circuit of the invention.
  • the receiving circuit of the invention is shown "in Fig. 1 incorporated in one channel of a voicefrequency carrier telegraph system.
  • a receiving lter or other selective network I is provided in the input of the circuit for selecting from the carrier modulated telegraph signal waves received over the transmission line L the particular frequencies assigned to that channel.
  • the output of the filter l is connected through the gaincontrol potentiometer 2 and input transformer 3 to the input of an ampliiier comprising two pentode amplifying vacuum tubes T1 and T2 coupled in tandem through the resistance-condenser coupling circuit 4, the nrst pentode tube T1 preferably being of the variable-mu type.
  • the transformer 5 couples the output of the second tube stage T2 of ⁇ the amplifier across the input diagonal of the full-wave copper-oxide detector bridge D.
  • An adjustable potentiometer 6 shunted by the by-pass condenser 1 is connected directly across the output diagonal of the detector D.
  • a third tube T3 also of the pentode vacuum tube type has its control grid-cathode circuit connected across the potentiometer 6.
  • the anodecathode circuit of tube T3 includes the windings of the polar receiving relay RR, so that the current output (approximately milliamperes) of the tube, when signals are applied to its control grid-cathode circuit, will operate the relay.
  • Plate current is supplied from plate battery 8 to the plate of the tube T1 through the resistance 9 of the interstage coupling circuit 4, to the 'plate of the tube T2 through the primary winding of output transformer 5 and to the plate of the tube Ta through part of the windings of the relay RR.
  • Suitable heating current is supplied from the filament battery I0 through the series resistance Il to the heaters of the heater type cathodes of the tubes T1, T2 and Ti/in series.
  • the suppressor grids of the tubes T1 and T2 are connected directly to the cathodes of the respective tubes.
  • the screen grid of the tube T1 is shown connected directly to ground, which is 20 volts above cathode potential, the screengrid of the tube T2 is connected directly to the positive terminal of plate battery 8 and the screen grid of the tube T3 is connected directly to the plate of that tube.
  • the screen grids of the tubes may, of course, be connected to other points of positive potential.
  • the parallel resistance-condenser grid biasing arrangement I2 is connected in the cathodecontrol grid circuit of the tube T2.
  • the control grid of the tube T3 is connected to the upper terminal I4 of the potentiometer resistance 6 through the large series resistance (10 megohms) I3.
  • the suppressor grid of the tube T3 is connected to the variable tap I5 on the potentiometer 6.
  • a resistance I6 in parallel with the compensating condenser I'I is connected in the control grid-cathode circuit of the tube Ti between the cathode thereof and the lower terminal of the secondary winding of input transformer 3, so that the negative terminal of condenser I'I is connected to the control grid of tube T1.
  • the lower terminal I8 of the potentiometer 6 is connected to a point between the parallel resistancecondenser network I6, I'I and the secondary Winding of the transformer 3, so that the latter network is connected also in common to the control grid-cathode and the suppressor grid-'cathode circuits of the tube T3, and the negative terminal of condenser II is connected to the control grid and suppressor grid of tube T3.
  • a xed negative bias is supplied from the filament battery Ill to the suppressor and control grids of tube T3 over paths which may be traced from the negative terminal of that battery through resistances II and IG and the lower portion of potentiometer 6 to the tap I5 thereon, from tap I5 directlyto the suppressor grid, and from tap I5 through the upper portion of potentiometer 6 and resistance I3 in series to the control grid.
  • the 'Ihe plate battery 8 supplies biasing current to the windings of the receiving relay RR through the resistances I9, and the by-pass condenser 20 is connected between the plate and the cathode across the windings of the relay.
  • the armature of the receiving relay RR is connected to a receiving telegraph loop
  • the battery Bi is connected to the receiving loop
  • the battery B2 is connected to the receiving loop, respectively, to actuate sounder or other apparatus to indicate marking and spacing signals in accordance with well-known telegraph practice.
  • the relay 'I'he receiving relay RR is initially adjusted, for example, by proper selection of the values of resistances I9 in the biasing circuit to make the amount of biasing current supplied to its windings from battery 8 such that the relay will operate to and fro in response to the plate current of the controlling tube Ta as nearly at the midpoint on the tube characteristic as isv feasible.
  • the relay will pick up and fall away at the proper time intervals depending on the length of the applied marking and spacing signals for a given intensity of the received signals.
  • the circuit of the, invention operates in the following manner to prevent the advance or retarding of the pick-up and fallaway times of the relay, or changes in signal bias, tending to change the marking and spacing signal durations, with changes in level of the applied signals.
  • the incoming carrier wave modulated with the marking and spacing signals generated at the transmitting end of the system (not shown), received over the transmission line L are impressed on the receiving filters in the receiving channels at the receiving station. That portion within the frequency range of the receiving lter I in the receiving channel, illustrated in detail in Fig. 1, will be passed thereby and with an intensity regulated by the setting of the potentiometer 2 will be impressed by the input transformer 3 on the input of the amplifier and will be amplified by the amplifying tubes T1 and T2 therein in accordance with the initial gain setting of these tubes,
  • the amplified waves in the output of the second tube T2 of the amplifier will be impressed by transformer 5 on the full wave copper-oxide detector bridge D and will be demodulated thereby.
  • 'I'he resulting unidirectional current with the carrier components largely filtered out by the condenser (0.05 microfarad) 1, will flow through the potentiometer resistance 6 producing a voltage drop therein which is applied to the control grid-cathode circuit of tube T3 connected across said potentiometer, operating as a direct-current amplifier.
  • the resulting amplified signal current in the plate-cathode circuit of the tube Ta will cause the operation of the receiving relay RR to its marking M contact in response to a received marking signal and to the spacing contact S, in response to a received spacing signal.
  • Direct-current amplification is used in the last amplifier stage inorder that a large output may be obtained from the high impedance pentode tube Ts.
  • I'his tube is worked at an unusually high negative control grid bias to provide a high degree of signal shaping, thereby making the signal bias more independent of receiving relay variations than would otherwise be the case.
  • the gain of the receiving circuit is automatically adjusted to compensate for changes in the received carrier level by the portion of the rectified output voltage of the copper-oxide detector D applied from the tap I5 of potentiometer E to the suppressor 'grid of the tube T3. 'I'he resulting grid current flow when the grids of tube T3 become positive, charges the compensator condenser I1 shunted by resistance I6. Due to the effect of the large resistance (10 megohms)y in the control grid circuit of the tube T3, the amount of control grid current flowing through resistance I6 is comparatively small, and the voltage drop in the resistance I5, therefore, will be mainly due to the flow of suppressor grid current of tube Ta therein.
  • the suppressor grid current of tube T3 flows through the lower portion of potentiometer 6, the resistances I6 and II and the 24-volt filament battery and ground, The current in this path is in such direction as to make the lower end of resistance IB negative, and this negative potential becomes the control grid potential of the variable-mu tube T1.
  • the charge applied to condenser I1 being proportional to the voltage drop produced in the potentiometer 6 by the detected signal variations in the output of the detector D, will be a function of the incoming carrier level.
  • the condenserresistance arrangement I1, I6 being common to the control grid-cathode circuits of the tubes T1 and T3, a negative potential varying in accordance with the signal variations will, therefore. be applied to the grids of these tubes and will cause a proportional adjustment of gain therein.
  • the negative terminal of the condenser I1 being connected to the control 4grid of the tube T1, the gain of that amplier tube will be varied in a direction and to an amount such as to tend to maintain the output voltage of the following detector D constant for an extended range of input variations.
  • a further compensating action is obtained in the last amplifier tube Ta, the control grid of which is also connected to the negative end of the compensating condenser I1.
  • a steeply rising signal wave front is obtained from the considerablv rounded carrier signal by biasing the control grid of the tube T3 supplying the relay operating current. well beyond cut-off so that a small percentage change in the signal voltage applied to the grid causes a large change in the plate current of the tube. .
  • the tube 'T3 selected for this purpose was one which requires a rather low value of negative grid bias to reduce the plate current to zero. This made it possible to use the filament battery to supply a grid biasing potential large compared to the cut-off potential thus making it unnecessary to use an auxiliary grid potential supply circuit.
  • a relatively large relay operating current is obtained from such a small tube by rectifying the carrier in the full-wave copper-oxide detector. suppressing the carrier frequencycomponents of demodulation and impressing the direct-current signal voltage on the grid of the tube T3. In this way, the full value of plate current of the tubey T3, as determined bv the static characteristic of the tube, is obtained.
  • This is an improvement over the Voice-frequency carrier telegraph receiving circuits 'of the prior art in which the carrier is supplied directly to the relay-controlling tube grid, so that plate current flows during only a small part of each carrier cycle.
  • the current which can be obtained from the tube in the latter case to actuate the relay is considerably less than that which would be ind!- cated by the static characteristic of the tube.
  • the problem may be stated as follows: In a level compensating device in which a voltage proportional to incoming level is established across the resistanceishunted condenser and used to control the gain of the receiving circuit, it is desired that the voltage remain practically ccnstant for a given line equivalent, regardless of the character of the signals being received. 'Ihat is, a voltage produced across the condenser when incoming current is modulated with telegraph signals.
  • the lvoltage ec Upon the closure of switch S, the lvoltage ec will practically reach a steady state value before the beginning of the next spacing signal, if the series resistance Rs is suciently small. Therefore, by suitably v choosing the constants in this simple circuit, the voltage across the condenser can be maintained at a fairly constant value regardless of the character of the signals being sent by the switch S. Furthermore, if the charging voltage E could be increased and the series resistance decreased momentarily when recharging the condenser after a spacing signal, the condenser voltage could be maintained at an even more nearly constant value.
  • the rectified signal voltage output of the copper-oxide detector D is impressed across potentiometer Ii on the control grid-cathode circuit of the pentode tube Ts. A portion of this voltage is applied to the suppressor grid of tube T3 from tap I5 of potentiometer 6. This gives rise to a iiow of grid current from the suppressor and control grids to the cathode. 'I'he control grid current is prevented from becoming very large by the large resistance I3 in series with the 'control grid. 'Ihe suppressor and control grid currents flow through compensator resistance I6 shunted by condenser Il, causing the terminal of that resistance connected to the grid of tube Ts to become negative.
  • the compensator voltage ec is a function of a resultant of two large opposing voltages. A small Vchange in one of the large voltages will produce a large change in the difference voltage. in a direction such as to tend to restore the condition existing before the change.
  • the condenser charge lost during a spacing signal will be restored very quickly during the following marking signal interval because of the low resistance in the charging path of the condenser Il due to the operated condition of the tube Ts during that interval.
  • the signal current in the output of tube T3 may be made to pass through the value required to operate the receiving relay RR at the proper time intervals to produce undistorted signals.
  • Fig. 2 in which changes in input level of the circuit expressed in decibels (db.) are plotted as abscissae and the percentage of telegraph signal bias (at 23 dots per second) is plotted as ordinates. As shown, the percentage of signal bias remains substantially constant over a wide range of input levels extending from zero to 45 decibels.
  • the gain control circuit employing the suppressor grid current of a pentode tube is adapted for use in ⁇ Iother types of signaling systems, for example, in connection with wire or radio telephone systems.
  • potentiometer 2 used for obtaining initial adjustment of the circuit may be connected across the secondary Winding of the input transformer 3 instead of across the primary winding as shown.
  • a circuit for compensating for the variations in amplitude level of transmitted signals in a signal transmission circuit comprising an electron discharge device connected in said circuit, having a cathode, an anode, and a control grid and a second grid spaced consecutively between said cathode and said anode, means positively biasing said anode with respect to said cathode, circuits respectively connecting said control grid and said second grid to said cathode, means to impress said signals on the control grid-cathode circuit, means to apply to said second grid a direct-current voltage varying in accordance with the level of said signals, and means to utilize the variations in the current produced in the second grid cathode circuit when said second grid is driven positive by the applied voltage to control the gain of said transmission circuit in such manner as to produce the desired compensation for signal level variations.
  • the level compensating circuit of claim l, iniyvhich the last-mentioned means comprises a network consisting of capacity and resistance in parallel, connected in common to said control grid-cathode circuit and said second grid-cathode circuit so that the varying voltage produced across said network by the current flowing in said second grid-cathode circuitcontrols the bias on said control grid and thus the gain of said device, and means to reduce the flow of control grid current through said resistance when said control grid is drivenpositive by the impressed signals to a small amount compared to the ow of current therethrough from said second grid.
  • means for compensating for variations in the amplitude level of transmitted signals comprising a variable-mu amplifying electron discharge device having a control electrode, connected in said circuit, a second electron discharge device having electrodes including a cathode, an anode, a control grid and a suppressor grid spaced between said control grid and said anode, circuits respectively connecting said control grid and said suppressor grid to said cathode, said anode being positively biased with respect to said cathode, means applying a fixed negative bias respectively to said control grid and said suppressor grid, a network comprising capacity and resistance in parallel connected in series in the supressor gridcathode circuit of said second device, means to impress said signafs on the control grid-cathode circuit of said second device, means to apply to said suppressor grid a direct current voltage varying in accordance with the level variations of said signals, and means to apply the voltage produced across said network in response to the varying current iiowing in said suppressor grid-cath
  • a carrier telegraph receiving circuit comprising means for amplifying received telegraph waves, means for detecting the telegraph signals therefrom, a telegraph relay controlled by the I detected singals, and means for reducing distortion in said circuit including telegraph bias ⁇ with changes in the amplitude level of the received waves, comprising an electron discharge device connected between said 'detecting means and said relay, including a cathode, an anode, a control grid and a suppressor grid, circuits respectively connecting each of the grids to said cathode, means positively biasing said anode with respect to said cathode, means respectively negatively biasing said control grid and said suppressor grid with respect t said cathode, the bias on said control grid being relatively large, a network comprising a parallel condenser and resistance in said suppressor grid-cathode circuit, means for impressing the detected signals on the control gridcathode circuit of said device, means to apply a direct-current voltage varying in accordance with the level variations of the detected signals on said suppressor
  • a carrier telegraph receiving circuit comprising means to amplify received carrier modulated telegraph signals, means to 'detect from the amplified Wave the low-frequency signal components while suppressing the carrier componets, an electron discharge device ⁇ having electrodes including a cathode, an anode, and a control grid and a suppressor grid spaced consecutively between said cathode and said anode, and circuits therefor, a telegraph relay ⁇ connected in the anode-cathode circuit of said device so that its operation is controlled by the anode current therein, said control grid and said suppressor grid being respectively negatively biased with respect to said cathode, with the control grid bias substantially larger, means to impress the low-frequency signal components of the detected waves on the control grid-cathode circuit of said device, means to utilize a portion of the energy of the low-frequency signal components in the detected waves to apply a direct-current voltage to said suppressor grid varying in accordance with the.
  • anetwork comprising capacity and resistance ⁇ in parallel connected in the suppressor grid-cathode circuit of said device, and means to utilize the varying voltage produced across said network by the current flowing in said suppressor grid-cathode cirtrol grid circuit, said network being connected in said control grid circuit sothat the voltage acrossl said network controls the gain yof lsbaidvariablemu tube.
  • the detecting means comprises a full-wave copper-oxide rect.
  • the means for impressing the low-frequency signal components of the detected waves on the control grid-cathode circuit of the first electron discharge device comprises a potentiometer resistance shunted by a by-pass condenser, common to said control grid-cathode circuit and the output of said full-wave rectifier
  • the means for applying said direct-current voltage to said suppressor grid comprises a connection from that grid to a tap on said potentiometer resistance
  • said amplifying means comprises a variable-mu electron discharge device includingV a control grid circuit
  • said network is also connected in common tothe control grid circuit of said variable-mu tube and the control grid-cathode circuit of the rst discharge device, so that the voltage produced across said network controls the gain telegraph signals from the received waves
  • a telegraph relay responsive to the detected signals
  • a network in series with the input of said amplifier comprising a capacitor and a discharge resistor in parallel
  • means responsive to the detected signals to charge said capacitor to a potential which is proportional to the amplitude level of 'the detector output to varythe gain of said amplifier so as to compensate for distortion in the signals controlling said relay caused by variations in the amplitude level of said received waves, and means to lreduce variations in the voltage" produced across said network due to the varying length of successive telegraph marking' signals comprising an electron discharge device connected between said detector and said network providing a low resistance in the charging path for said capacitor to enable it to be quickly
  • said electron discharge device comprises a single amplifying vacuum tube having a heated cathode, an anode positively biased with respect to said cathode, a control grid and a second grid electrode spaced between said cathode and anode, both negatively biased with respect toxsaid cathode, and circuits respectively connectingv said cathode to said control grid and said second grid electrode, the output of said detector beingv connected to the control grid-cathode circuit of said tube acrossa potentiometer resistance, the second grid electrode-cathode circuit of said tube including a portion of said potentiometer resistance and said network in series.

Landscapes

  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Amplifiers (AREA)
US208790A 1938-05-19 1938-05-19 Reduction of distortion in signal transmission systems Expired - Lifetime US2182841A (en)

Priority Applications (3)

Application Number Priority Date Filing Date Title
BE434405D BE434405A (en, 2012) 1938-05-19
US208790A US2182841A (en) 1938-05-19 1938-05-19 Reduction of distortion in signal transmission systems
FR854639D FR854639A (fr) 1938-05-19 1939-05-11 Systèmes de transmission de signaux électriques

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US208790A US2182841A (en) 1938-05-19 1938-05-19 Reduction of distortion in signal transmission systems

Publications (1)

Publication Number Publication Date
US2182841A true US2182841A (en) 1939-12-12

Family

ID=22776074

Family Applications (1)

Application Number Title Priority Date Filing Date
US208790A Expired - Lifetime US2182841A (en) 1938-05-19 1938-05-19 Reduction of distortion in signal transmission systems

Country Status (3)

Country Link
US (1) US2182841A (en, 2012)
BE (1) BE434405A (en, 2012)
FR (1) FR854639A (en, 2012)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2552362A (en) * 1946-01-31 1951-05-08 Phillips Petroleum Co Telegraph receiving circuit

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2552362A (en) * 1946-01-31 1951-05-08 Phillips Petroleum Co Telegraph receiving circuit

Also Published As

Publication number Publication date
FR854639A (fr) 1940-04-19
BE434405A (en, 2012)

Similar Documents

Publication Publication Date Title
US2153202A (en) Electrical filter
US2384456A (en) Radio receiving system
US2182841A (en) Reduction of distortion in signal transmission systems
US2447564A (en) Noise reducing circuits
US2223982A (en) Radio system
US2034226A (en) Wave signaling system
US2425063A (en) Telegraphic keying bias adjuster
US2393921A (en) Radio telegraph receiving arrangement
US2282271A (en) Electrical signaling system
US2343753A (en) Receiving circuit for telegraph signaling systems
US2247328A (en) Receiving circuit for signaling systems
US2552362A (en) Telegraph receiving circuit
US1950145A (en) Volume-control system
US2248857A (en) Automatic bias corrector
US2676204A (en) Pulse demodulating circuit
US2390850A (en) Unbalance correcting amplifier system
US2026357A (en) Automatic volume control
US2598996A (en) Electric carrier wave signaling system
US2073038A (en) Radio receiving system
US2785303A (en) Noise limiter
US2056000A (en) Signaling
US1990512A (en) Radioreceiver
US2300366A (en) Signal transmission system
US2655596A (en) Automatic gain control circuit
US2001950A (en) Automatic volume control