US2890333A - Delay network - Google Patents

Delay network Download PDF

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US2890333A
US2890333A US529432A US52943255A US2890333A US 2890333 A US2890333 A US 2890333A US 529432 A US529432 A US 529432A US 52943255 A US52943255 A US 52943255A US 2890333 A US2890333 A US 2890333A
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delay
tube
adjustable
grid
cathode
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US529432A
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Manvel K Zinn
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AT&T Corp
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Bell Telephone Laboratories Inc
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B3/00Line transmission systems
    • H04B3/02Details
    • H04B3/04Control of transmission; Equalising
    • H04B3/14Control of transmission; Equalising characterised by the equalising network used
    • H04B3/146Control of transmission; Equalising characterised by the equalising network used using phase-frequency equalisers
    • H04B3/148Control of transmission; Equalising characterised by the equalising network used using phase-frequency equalisers variable equalisers

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  • This invention relates to wave transmission networks and more particularly to adjustable delay networks.
  • the principal object of the invention is to introduce an adjustable delay in a wave transmission circuit. Another object is to provide such a delay without introducing insertion loss. A further object is to control the delay by adjusting only resistors.
  • wave transmission systems such, for example, as television, telephoto or radio systems it is often required to introduce a corrective delay characteristic which can be easily and quickly adjusted in magnitude or shape. It is also desirable that no insertion loss be associated with the delay.
  • the adjustable delay network in accordance with the present invention is of the all-pass type and thus introduces no loss.
  • the network comprises an electron tube having a cathode, a plate and a grid, a reactive feedback impedance connected between the plate and the grid, and an adjustable output resistor connected between the plate and the cathode.
  • the conductance of the resistor and the transconductance of the tube are substantially equal, thus making the insertion loss zero.
  • Means, preferably under a unitary control, are provided for adjusting both the conductance and the transconductance while maintaining their equality.
  • the conductance is controlled by adjusting the resistor.
  • the transconductance may be adjusted by means of a second adjustable resistor which controls the bias on the grid of the tube.
  • the delay shape depends upon the choice of the reactive impedance. For example, a hump of delay may be provided. A further adjustment of the delay shape may be provided, if desired, by making the reactive impedance adjustable.
  • the delay network is preferably inserted between high impedance at both ends. It may, for example, be employed as an interstage between two other electron-tube stages.
  • the input stage may be a pentode and the output stage of any type having a high grid impedance.
  • FIG. 1 is a schematic circuit of an adjustable delay network in accordance with the invention employed as an interstage between two other stages;
  • Fig. 2 shows one type of delay-frequency characteristic obtainable with the network of Fig. 1.
  • the over-all circuit comprises three electron-tube stages connected in tandem between a pair of input terminals 3, 4 and a pair of output terminals 5, 6.
  • the signal wave to be equalized is impressed upon the input terminals 3, 4 and a suitable load may be connected to the output terminals 5, 6.
  • the central stage constitutes the delay network proper. It com- Patented June 9, 1959 prises an electron tube 8 having a cathode 9, a plate 10 and a control grid 11. As shown, the tube 8 is a pentode, which has three grids. It will be understood, however, that a mode or other type of tube may be employed instead.
  • a reactive feedback impedance 13 is connected between the plate 10 and the grid 11, and an adjustable output resistor 14 between the plate 10 and the cathode 9.
  • a second adjustable resistor 15 is connected in the cathode circuit to control the bias on the grid 11 and, thereby, the transeonductance of the tube 8.
  • the resistors 14 and 15 are preferably ganged together for operation under a single control, as indicated by the dashed line 16.
  • the impedance connected to the input end of the delay network is provided by the first stage. As shown, this stage comprises a pentode tube 18. The input of the tube 18 is connected to the input terminals 3 and 4 through a transformer 19 which has a grounded shield 20 between the windings. The first two stages are coupled through a shunt resistor 21 which ordinarily has a high resistance. The last stage, comprising a triode tube 22, furnishes the desired high impedance at the output end of the delay network. The output of the tube 22 is con nected to the output terminals 5 and 6 through a second transformer 23 with a grounded shield 24 between the windings.
  • the operating voltages for all three stages are obtained from the source 25, shown as a battery.
  • the customary by-pass capacitors 27, 28, 29, 30, 31, and 32, of high capacitance, are inserted to separate the power supply from the signal circuits.
  • the resistors 33 and 34 provide grid leaks.
  • the voltage transfer ratio R of the delay network is given by js+b (1) Since b and g are maintained equal for all adjustments, it is seen that the modulus of R is always unity. Therefore, like an all-pass network, there is no loss at any frequency.
  • any of a large variety of delay-frequency characteristics may be provided.
  • the impedance 13 is constituted by the series combination of a capacitor of value C and an inductor of value L, as shown in Fig. l, a hump of delay is obtained.
  • a typical shape is shown in Fig. 2, in which delay is plotted against frequency.
  • the delay T at zero frequency is The maximum delay occurs approximately at the resonant frequency f given by It is thus seen that T varies directly with C and inversely with b, and T varies directly with both L and b. Therefore, assuming that C and L are fixed, the height and shape of the characteristic may be adjusted by changing the value of b.
  • the value of the resistor 14 is adjusted by adjusting the value of the resistor 14.
  • the shape may be further changed, if desired, by adjusting the value of C or L.
  • These elements may be made adjustable for this purpose, as indicated by the arrows.
  • the value of the transcond-uctance g is maintained equal to b as b is varied. This is accomplished by adjusting the value of the resistor 15, which is preferably ganged to the resistor 14, as indicated.
  • An adjustable all-pass delay network comprising an electron tube having a cathode, a plate, and a grid, a reactive feedback impedance connected between the plate and the grid, an adjustable output resistor connected be tween the plate and the cathode, an adjustable resistor connected to the cathode to control the transconductance of the tube, the conductance of the output resistor and the transconductance being substantially equal, and unitary means for adjusting the resistors while maintaining the equality of the conductance and the transconductance.
  • An adjustable all-pass delay network including three electron-tube stages connected in tandem, the central stage comprising an electron tube having a cathode, a plate, and a control grid, a reactive feedback impedance connected between the plate and the grid, an adjustable output resistor connected between the plate and the cathode, a second adjustable resistor connected to the cathode to control the transconductance of the tube, the conductance of the output resistor and the transconductance being substantially equal, and unitary means for adjusting the resistors while maintaining this equality.
  • An adjustable delay network comprising an electron tube having a cathode, a plate, and a grid, a circuit having a reactive impedance connected between said plate and said grid, a first adjustable resistor connected between said plate and said cathode, a second adjustable resistor connected to said cathode for controlling the grid bias voltage of said tube, and a unitary control for the two resistors to maintain the conductance of said first resister at all times substantially equal to the transconductance of said tube.

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Networks Using Active Elements (AREA)

Description

M. K. ZINN DELAY NETWORK June 9, 1959 Filed Aug. 19. 1955 FIG. I
FIG.Z
FREQUENCY INVENTOR M K. Z/lV/V ATTORNEY United States Patent DELAY NETWORK Manvel K. Manhasset, N.Y., assignor to Bell Telephone Ilahoratories, Incorporated, New York, N.Y., a corporation of New York Application August 19, 1955, Serial No. 529,432
3 'Claims. (Cl. 250-27) This invention relates to wave transmission networks and more particularly to adjustable delay networks.
The principal object of the invention is to introduce an adjustable delay in a wave transmission circuit. Another object is to provide such a delay without introducing insertion loss. A further object is to control the delay by adjusting only resistors.
In wave transmission systems such, for example, as television, telephoto or radio systems it is often required to introduce a corrective delay characteristic which can be easily and quickly adjusted in magnitude or shape. It is also desirable that no insertion loss be associated with the delay.
The adjustable delay network in accordance with the present invention is of the all-pass type and thus introduces no loss. The network comprises an electron tube having a cathode, a plate and a grid, a reactive feedback impedance connected between the plate and the grid, and an adjustable output resistor connected between the plate and the cathode. The conductance of the resistor and the transconductance of the tube are substantially equal, thus making the insertion loss zero. Means, preferably under a unitary control, are provided for adjusting both the conductance and the transconductance while maintaining their equality. The conductance is controlled by adjusting the resistor. The transconductance may be adjusted by means of a second adjustable resistor which controls the bias on the grid of the tube. These two resistors may be ganged together under a unitary control. Thus, by operating this single control, the magnitude or shape of the delay characteristic can be adjusted as desired. The delay shape depends upon the choice of the reactive impedance. For example, a hump of delay may be provided. A further adjustment of the delay shape may be provided, if desired, by making the reactive impedance adjustable.
For best results, the delay network is preferably inserted between high impedance at both ends. It may, for example, be employed as an interstage between two other electron-tube stages. The input stage may be a pentode and the output stage of any type having a high grid impedance.
The nature of the invention and its various objects, features and advantages will appear more fully in the following detailed description of a typical embodiment illustrated in the accompanying drawing, of which Fig. 1 is a schematic circuit of an adjustable delay network in accordance with the invention employed as an interstage between two other stages; and
Fig. 2 shows one type of delay-frequency characteristic obtainable with the network of Fig. 1.
As shown in Fig. l, the over-all circuit comprises three electron-tube stages connected in tandem between a pair of input terminals 3, 4 and a pair of output terminals 5, 6. The signal wave to be equalized is impressed upon the input terminals 3, 4 and a suitable load may be connected to the output terminals 5, 6. The central stage constitutes the delay network proper. It com- Patented June 9, 1959 prises an electron tube 8 having a cathode 9, a plate 10 and a control grid 11. As shown, the tube 8 is a pentode, which has three grids. It will be understood, however, that a mode or other type of tube may be employed instead. A reactive feedback impedance 13 is connected between the plate 10 and the grid 11, and an adjustable output resistor 14 between the plate 10 and the cathode 9. A second adjustable resistor 15 is connected in the cathode circuit to control the bias on the grid 11 and, thereby, the transeonductance of the tube 8. The resistors 14 and 15 are preferably ganged together for operation under a single control, as indicated by the dashed line 16.
The impedance connected to the input end of the delay network is provided by the first stage. As shown, this stage comprises a pentode tube 18. The input of the tube 18 is connected to the input terminals 3 and 4 through a transformer 19 which has a grounded shield 20 between the windings. The first two stages are coupled through a shunt resistor 21 which ordinarily has a high resistance. The last stage, comprising a triode tube 22, furnishes the desired high impedance at the output end of the delay network. The output of the tube 22 is con nected to the output terminals 5 and 6 through a second transformer 23 with a grounded shield 24 between the windings.
The operating voltages for all three stages are obtained from the source 25, shown as a battery. The customary by- pass capacitors 27, 28, 29, 30, 31, and 32, of high capacitance, are inserted to separate the power supply from the signal circuits. The resistors 33 and 34 provide grid leaks. v
If the feedback impedance 13 has a pure susceptance js, the output resistor 14 a conductance b, and the tube 8 a transconductance g, the voltage transfer ratio R of the delay network is given by js+b (1) Since b and g are maintained equal for all adjustments, it is seen that the modulus of R is always unity. Therefore, like an all-pass network, there is no loss at any frequency.
However, by suitably selecting the impedance 13, any of a large variety of delay-frequency characteristics may be provided. For example, if the impedance 13 is constituted by the series combination of a capacitor of value C and an inductor of value L, as shown in Fig. l, a hump of delay is obtained. A typical shape is shown in Fig. 2, in which delay is plotted against frequency. The delay T at zero frequency is The maximum delay occurs approximately at the resonant frequency f given by It is thus seen that T varies directly with C and inversely with b, and T varies directly with both L and b. Therefore, assuming that C and L are fixed, the height and shape of the characteristic may be adjusted by changing the value of b. This is done by adjusting the value of the resistor 14. The shape may be further changed, if desired, by adjusting the value of C or L. These elements may be made adjustable for this purpose, as indicated by the arrows. In order to keep the loss zero, the value of the transcond-uctance g is maintained equal to b as b is varied. This is accomplished by adjusting the value of the resistor 15, which is preferably ganged to the resistor 14, as indicated.
It is to be understood that the above-described arrangement is illustrative of the application of the principles of the invention. Numerous other arrangements may be devised by those skilled in the art without departing from the spirit and scope of the invention.
What is claimed is:
1. An adjustable all-pass delay network comprising an electron tube having a cathode, a plate, and a grid, a reactive feedback impedance connected between the plate and the grid, an adjustable output resistor connected be tween the plate and the cathode, an adjustable resistor connected to the cathode to control the transconductance of the tube, the conductance of the output resistor and the transconductance being substantially equal, and unitary means for adjusting the resistors while maintaining the equality of the conductance and the transconductance.
2. An adjustable all-pass delay network including three electron-tube stages connected in tandem, the central stage comprising an electron tube having a cathode, a plate, and a control grid, a reactive feedback impedance connected between the plate and the grid, an adjustable output resistor connected between the plate and the cathode, a second adjustable resistor connected to the cathode to control the transconductance of the tube, the conductance of the output resistor and the transconductance being substantially equal, and unitary means for adjusting the resistors while maintaining this equality.
3. An adjustable delay network comprising an electron tube having a cathode, a plate, and a grid, a circuit having a reactive impedance connected between said plate and said grid, a first adjustable resistor connected between said plate and said cathode, a second adjustable resistor connected to said cathode for controlling the grid bias voltage of said tube, and a unitary control for the two resistors to maintain the conductance of said first resister at all times substantially equal to the transconductance of said tube.
References Cited in the file of this patent UNITED STATES PATENTS 2,273,143 Roberts Feb. 17, 1942 2,351,934 De Kramolin June 20, 1944 2,456,029 Snyder Dec. 14, 1948 2,532,534 Bell Dec. 5, 1950 2,594,104 Washburn Apr. 22, 1952 2,658,958 Wells Nov. 10, 1953 2,662,178 Levell Dec. 8, 1953 2,692,334 Blumlein Oct. 19, 1954 FOREIGN PATENTS 715,158 Great Britain Sept. 8, 1954
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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3022442A (en) * 1959-06-24 1962-02-20 Burroughs Corp Pulse generating circuits
US3093797A (en) * 1953-07-27 1963-06-11 Curtiss Wright Corp Pulse generator employing logic gates and delay means

Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2273143A (en) * 1940-07-05 1942-02-17 Rca Corp Audio volume control circuit
US2351934A (en) * 1944-06-20 Selectivity apparatus
US2456029A (en) * 1942-07-30 1948-12-14 Rca Corp Thermionic tube circuits
US2532534A (en) * 1946-06-21 1950-12-05 Jr Persa R Bell Sweep-voltage generator circuit
US2594104A (en) * 1943-12-16 1952-04-22 Us Navy Linear sweep circuits
US2658958A (en) * 1949-07-16 1953-11-10 Wilcox Gay Corp Negative feedback frequency response compensation amplifier system
US2662178A (en) * 1950-06-08 1953-12-08 Cossor Ltd A C Voltage generating circuit
GB715158A (en) * 1952-04-17 1954-09-08 James Neale Low-loss tuned circuits employing reactance valves
US2692334A (en) * 1942-06-05 1954-10-19 Emi Ltd Electrical circuit arrangement for effecting integration and applications thereof

Patent Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2351934A (en) * 1944-06-20 Selectivity apparatus
US2273143A (en) * 1940-07-05 1942-02-17 Rca Corp Audio volume control circuit
US2692334A (en) * 1942-06-05 1954-10-19 Emi Ltd Electrical circuit arrangement for effecting integration and applications thereof
US2456029A (en) * 1942-07-30 1948-12-14 Rca Corp Thermionic tube circuits
US2594104A (en) * 1943-12-16 1952-04-22 Us Navy Linear sweep circuits
US2532534A (en) * 1946-06-21 1950-12-05 Jr Persa R Bell Sweep-voltage generator circuit
US2658958A (en) * 1949-07-16 1953-11-10 Wilcox Gay Corp Negative feedback frequency response compensation amplifier system
US2662178A (en) * 1950-06-08 1953-12-08 Cossor Ltd A C Voltage generating circuit
GB715158A (en) * 1952-04-17 1954-09-08 James Neale Low-loss tuned circuits employing reactance valves

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3093797A (en) * 1953-07-27 1963-06-11 Curtiss Wright Corp Pulse generator employing logic gates and delay means
US3022442A (en) * 1959-06-24 1962-02-20 Burroughs Corp Pulse generating circuits

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