US1977435A - Method of aligning band-pass circuits - Google Patents

Method of aligning band-pass circuits Download PDF

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US1977435A
US1977435A US524704A US52470431A US1977435A US 1977435 A US1977435 A US 1977435A US 524704 A US524704 A US 524704A US 52470431 A US52470431 A US 52470431A US 1977435 A US1977435 A US 1977435A
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band
circuits
frequency
circuit
tuned
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US524704A
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Paul O Farnham
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RCA Corp
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RCA Corp
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    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03HIMPEDANCE NETWORKS, e.g. RESONANT CIRCUITS; RESONATORS
    • H03H7/00Multiple-port networks comprising only passive electrical elements as network components
    • H03H7/01Frequency selective two-port networks
    • H03H7/0153Electrical filters; Controlling thereof
    • H03H7/0161Bandpass filters

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  • This invention relates to tuned circuits and particularly to methods of aligning tuned Circuits of the band-pass type.
  • An object of the present invention is to provide a simple and effective method for aligning the two tuned circuits of a band-pass system with each other and/ or with other tuned circuits. More particularly, an object is to provide a meth- 0d of adjusting the resonant frequency band of a band-pass circuit by first eliminating or substantially eliminating the coupling between the tuned circuits of a band-pass unit, and then tuning each circuit to the same frequency.
  • FIG. 1 is a circuit diagram illustrative of the invention.
  • Fig. 2 is a curve sheet showing resonance curves indicative of the results obtained during the adjusting operation. 7
  • tuned band-pass circuits constitute the input system associated with the first amplifier tube 1, and the interstage coupling between that and the succeeding amplifier tube 2.
  • these stages may be considered to be tuned radio frequency amplifier stages of a radio receiver, but it will be apparent that the invention is generally applicable to the aligning of the coupled circuits of a band-pass unit, either tunable over a range of frequency or not tunable, irrespective of the particular apparatus or circuit arrangement in which the unit is to be incorporated.
  • one of the input terminals 3 of the amplifier is connected to ground and the other is connected to the high potential terminal of inductance L through a condenser 4.
  • the high potential terminal of a similar inductance L is connected to the control grid of tube 1, and the low potential terminals of the inductances are connected to ground through-the coupling impedance Cm.
  • Tuning condensers C are connected from the high potential terminals of each inductance to ground and small Vernier or aligning condensers 5 are preferably shunted across each tuning condenser C.
  • the interstage coupling system is of the same general form as the input system for the first tube, the inductance L of the first tuned circuit being connected, in series with a radio frequency choke 6, between the plate of tube 1 and an appropriate source B of plate current.
  • the adjustable elements of all of the tuning condensers are preferably connected mechanically to provide a single control for all of the tuned circuits.
  • the output circuit of the second amplifier stage is coupled, through a detector D, to a inilliammeter 8 and a signal generator of adjustable frequency, indicated diagrammatically by the tuned oscillator 9, is connected across the input terminals 3.
  • a signal generator and meter in testing or adjusting an amplifier is well known but, as stated above, considerable difficulty has been experienced in adjusting the trimming condensers to insure. alignment when one or more band-pass circuits are included in the amplifier.
  • the coupling impedances Cm of the band-pass circuits are then short-circuited out by low resistance shunts l0,
  • the curve 11 is a typical resonance curve for a bandpass circuit of the type including two tuned circuits having a small impedance in common.
  • the curve 11 is characterized by the presence of two resonance peaks, at frequencies f and f, and the width of the band is determined by the degree of coupling provided by the common impedance which,
  • the aligning process may therefore be carried out by impressing upon the input terminals 3 an oscillatory voltage of a frequency corresponding to the mean of frequencies f and f, and adjust ing the tuning condensers C to give a maximum or approximately maximum alternating current flow in the output circuit of the second stage, as indicated by the reading of the meter 8. If necessary, the connection between the main control shaft and the condensers C is adjusted to bring the scale reading of the control shaft into agreement with the frequency of the impressed voltage, which frequency is indicated by the adjustment of the signal generator 9. quency corresponds to the mean of the frequencies and f of the resonance curve 11.
  • shunts 10 are then applied to short circuit the coupling condensers Cm, and the signal generator is adjusted tothe frequency As indicated by resonance curve 12 of Fig. 2, the transmission through the amplifier is substantially reduced by the short-circuiting of the condensers Cm, butthe resonance peak is easily recognized.
  • the band-pass circuit is properly aligned, i. e., its resonance curve is substantially symmetrical about the desired mean frequency, when the.
  • the amplifier also includes one or more stages tuned by simple resonant circuits, the band-pass or the single resonance peaks are, of course, separately adjusted.
  • the generator 9 is adjusted, in the usual manner, to supply a voltage of the mean frequency, i. e. the frequency as indicated by the receiver scale graduations,
  • each of ci cuits includin inductances of substantially equal magnitude shunted by mechanically nterccnnected variable condensers of substantially identical construction and by trimming condensers; which method comprises impressing upon the band-pass circuit a voltage of the desired carrier frequency, adjusting said variable condensers to bring the band-pass circuit into resonance at approximately the carrier frequency, short-circuiting the.
  • said circuit comprising at least two tuned cir cuits coupled by an impedance, and each of said circuits including mechanically interconnected variable tuning elements of substantially identical construction and trimming tuning elements; which method comprises impressing upon the band pass circuit a voltage of the desired carrier frequency, adjusting said variable tuning elements to bring the band pass circuit into resonance at approximately the carrier frequency, short circuiting the coupling impedance, impressing upon the band pass circuit a voltage of the frequency of the lower limit of the transmission band and adjusting said trimming elements to secure a maximum transmission of said lower limit frequency by said band pass circuit and then removingthe short circuits.
  • a band pass circuit of the type including two tuned circuits coupled by a capacitive impedance which is common to said circuits each of said tuned circuits including an inductance.
  • a variable condenser and a trimming condenser the steps in a method of aligning said band pass circuit so as to afford substantially uniform transmission of all fre-' quencies lying within a band defined by two limiting frequencies at opposite sides of a desired earner frequency which comprise adjusting said variable condensers of each of the tuned circuits so asto produce maximum response in said circuits at the desired carrier frequency, shor circuiting the coupling impedance and adjusting said trimming'co'ndensers to bring both tuned circuits into resonance at the frequency of the lower peak of the resonance curve of the band pass circuit and subsequently removing the short circuit.
  • the desired carrier frequency decreasing to a substantial degree the coupling between the two coupled circuits, impressing upon the band pass circuit a voltage of approximately the frequency of one of. said two limiting frequencies of the lit transmission band and adjusting said trimming elements to secure substantially maximum transmission of the last impressed frequency by said band pass circuit and then increasing the degree of coupling between the circuits to its normal value.

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Description

Oct. 16, 1934. P. 0. FARNHAM METHOD OF ALIGNING BAND PASS CIRCUITS Filed March 23, 1951 l I TB -0 Z! 5 5 flefecfor I 5 M l regu vcy Patented Oct. 16, 1934 UNETED STATES PATENT seein METHOD OF ALIGNING BAND-PASS CIRCUITS Delaware Application March 23, 1931, Serial No. 524,704
4 Claims.
This invention relates to tuned circuits and particularly to methods of aligning tuned Circuits of the band-pass type.
It has been proposed to secure substantially 5 equal transmission for all frequencies within a narrow band and sharp attenuation for, frequencies outside of that band by the use of tuned circuits coupled with somewhat in excess of crit ical coupling. The resonance curve for such a system of coupled circuits is characterized by two resonance peaks and, when one or more band-pass circuits of this type are included in a transmission system in which tuning is effected by a single control element, it is difiicult so to align the adjustable elements of the system as to bring all of the tuned circuits into resonance at the same frequency. V
An object of the present invention is to provide a simple and effective method for aligning the two tuned circuits of a band-pass system with each other and/ or with other tuned circuits. More particularly, an object is to provide a meth- 0d of adjusting the resonant frequency band of a band-pass circuit by first eliminating or substantially eliminating the coupling between the tuned circuits of a band-pass unit, and then tuning each circuit to the same frequency.
These and other objects of the invention will be apparent from the following specification when taken with the accompanying drawing, in which Fig. 1 is a circuit diagram illustrative of the invention, and
Fig. 2 is a curve sheet showing resonance curves indicative of the results obtained during the adjusting operation. 7
As shown diagrammatically in Fig. 1, tuned band-pass circuits constitute the input system associated with the first amplifier tube 1, and the interstage coupling between that and the succeeding amplifier tube 2. For purposes of illustration, these stages may be considered to be tuned radio frequency amplifier stages of a radio receiver, but it will be apparent that the invention is generally applicable to the aligning of the coupled circuits of a band-pass unit, either tunable over a range of frequency or not tunable, irrespective of the particular apparatus or circuit arrangement in which the unit is to be incorporated.
As shown in Fig. 1, one of the input terminals 3 of the amplifier is connected to ground and the other is connected to the high potential terminal of inductance L through a condenser 4. The high potential terminal of a similar inductance L is connected to the control grid of tube 1, and the low potential terminals of the inductances are connected to ground through-the coupling impedance Cm. Tuning condensers C are connected from the high potential terminals of each inductance to ground and small Vernier or aligning condensers 5 are preferably shunted across each tuning condenser C.
The interstage coupling system is of the same general form as the input system for the first tube, the inductance L of the first tuned circuit being connected, in series with a radio frequency choke 6, between the plate of tube 1 and an appropriate source B of plate current. As indicated by the broken lines extending from the several tuning condensers C to the control bar 7, the adjustable elements of all of the tuning condensers are preferably connected mechanically to provide a single control for all of the tuned circuits.
To efiect the desired alignment of the stages, the output circuit of the second amplifier stage is coupled, through a detector D, to a inilliammeter 8 and a signal generator of adjustable frequency, indicated diagrammatically by the tuned oscillator 9, is connected across the input terminals 3. This use of a signal generator and meter in testing or adjusting an amplifier is well known but, as stated above, considerable difficulty has been experienced in adjusting the trimming condensers to insure. alignment when one or more band-pass circuits are included in the amplifier. I
In accordance with the invention, the coupling impedances Cm of the band-pass circuits are then short-circuited out by low resistance shunts l0,
and the-several trimming condensers 5 are adjusted to give a maximum current flow in the output circuit of the second stage, i. e., a maximum current flow as indicated by the meter 8.
Referring now to Fig. 2, the curve 11 is a typical resonance curve for a bandpass circuit of the type including two tuned circuits having a small impedance in common. The curve 11 is characterized by the presence of two resonance peaks, at frequencies f and f, and the width of the band is determined by the degree of coupling provided by the common impedance which,
in the illustrated circuit, is capacitive. In the absence of the coupling impedance Cm, the tuned circuitsare resonant at the lower frequency 1, and I have discovered that, in practical constructions, there is an appreciable residual transmission of alternating currents of the frequency when the coupling condensers Cm are short circuited.
The aligning process may therefore be carried out by impressing upon the input terminals 3 an oscillatory voltage of a frequency corresponding to the mean of frequencies f and f, and adjust ing the tuning condensers C to give a maximum or approximately maximum alternating current flow in the output circuit of the second stage, as indicated by the reading of the meter 8. If necessary, the connection between the main control shaft and the condensers C is adjusted to bring the scale reading of the control shaft into agreement with the frequency of the impressed voltage, which frequency is indicated by the adjustment of the signal generator 9. quency corresponds to the mean of the frequencies and f of the resonance curve 11. The
shunts 10 are then applied to short circuit the coupling condensers Cm, and the signal generator is adjusted tothe frequency As indicated by resonance curve 12 of Fig. 2, the transmission through the amplifier is substantially reduced by the short-circuiting of the condensers Cm, butthe resonance peak is easily recognized. The
several tuned circuits are aligned, by adjustment of the trimming condensers 5, to give a maximum current flow through the milliammeter 8.
By thus aligning the several LC circuits, the band-pass circuit is properly aligned, i. e., its resonance curve is substantially symmetrical about the desired mean frequency, when the.
shunts 10 are removed. When the amplifier includes more than one band-pass7circuit all of.
the circuits are properly aligned and, if the same circuit constants are employed in all of the bandpass circuits, the several resonance bands are all of the same width. I
When the amplifier also includes one or more stages tuned by simple resonant circuits, the band-pass or the single resonance peaks are, of course, separately adjusted. In the case of the single tuned circuit couplings, the generator 9 is adjusted, in the usual manner, to supply a voltage of the mean frequency, i. e. the frequency as indicated by the receiver scale graduations,
within a defined by two limiting frequencies at opposite sides of a desired carrier frequency, said circuit r'ing two tuned circuits coupled by a capaci ive impedance, and each of ci cuits includin inductances of substantially equal magnitude shunted by mechanically nterccnnected variable condensers of substantially identical construction and by trimming condensers; which method comprises impressing upon the band-pass circuit a voltage of the desired carrier frequency, adjusting said variable condensers to bring the band-pass circuit into resonance at approximately the carrier frequency, short-circuiting the. coupling impedances, impressing upon the band-pass circuit This fre-' a voltage of the frequency of the lower limit of the transmission band, and adjusting said trimming condensers to seems a maximum transmission of said lower limit frequency by said bandpass circuit, and then removing the short cir cuitsc 2; The method of adjusting a band pass circuit of the type intended to afford substantially uniform transmission of all frequencies lying within a band defined by two limiting frequencies at opposite sidesof a. desired carrier frequency, said circuit comprising at least two tuned cir cuits coupled by an impedance, and each of said circuits including mechanically interconnected variable tuning elements of substantially identical construction and trimming tuning elements; which method comprises impressing upon the band pass circuit a voltage of the desired carrier frequency, adjusting said variable tuning elements to bring the band pass circuit into resonance at approximately the carrier frequency, short circuiting the coupling impedance, impressing upon the band pass circuit a voltage of the frequency of the lower limit of the transmission band and adjusting said trimming elements to secure a maximum transmission of said lower limit frequency by said band pass circuit and then removingthe short circuits.
3. In the operation of a band pass circuit of the type including two tuned circuits coupled by a capacitive impedance which is common to said circuits each of said tuned circuits including an inductance. shunted by a variable condenser and a trimming condenser, the steps in a method of aligning said band pass circuit so as to afford substantially uniform transmission of all fre-' quencies lying within a band defined by two limiting frequencies at opposite sides of a desired earner frequency which comprise adjusting said variable condensers of each of the tuned circuits so asto produce maximum response in said circuits at the desired carrier frequency, shor circuiting the coupling impedance and adjusting said trimming'co'ndensers to bring both tuned circuits into resonance at the frequency of the lower peak of the resonance curve of the band pass circuit and subsequently removing the short circuit.
4. The method of adjusting a band pass circuit of the type intended to afford substantially uniform transmission of all frequencies lying 1 u within a band of frequencies defined by two limiting frequencies at opposite sides of a desired carrier frequency, said circuit comprising at least two tuned circuits coupled by an impedance and each of said circuits including mechanically interconnected variable tuning elements; which method comprises, impressing upon the band pass circuit a voltage of the desired carrier frequency, adjusting staid variable tuning elements so as to produce approximately maximum response 8.17
the desired carrier frequency, decreasing to a substantial degree the coupling between the two coupled circuits, impressing upon the band pass circuit a voltage of approximately the frequency of one of. said two limiting frequencies of the lit transmission band and adjusting said trimming elements to secure substantially maximum transmission of the last impressed frequency by said band pass circuit and then increasing the degree of coupling between the circuits to its normal value.
PAUL O. FARNHAM.
US524704A 1931-03-23 1931-03-23 Method of aligning band-pass circuits Expired - Lifetime US1977435A (en)

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Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2991436A (en) * 1958-09-11 1961-07-04 Western Electric Co Adjustment of frequency sensitive transmission networks
US4123732A (en) * 1977-01-31 1978-10-31 The United States Of America As Represented By The Secretary Of The Navy Method of making tuned resonance passive electronic filters

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2991436A (en) * 1958-09-11 1961-07-04 Western Electric Co Adjustment of frequency sensitive transmission networks
US4123732A (en) * 1977-01-31 1978-10-31 The United States Of America As Represented By The Secretary Of The Navy Method of making tuned resonance passive electronic filters

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