US2323376A - Variable permeability tuning system - Google Patents

Variable permeability tuning system Download PDF

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US2323376A
US2323376A US331966A US33196640A US2323376A US 2323376 A US2323376 A US 2323376A US 331966 A US331966 A US 331966A US 33196640 A US33196640 A US 33196640A US 2323376 A US2323376 A US 2323376A
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tuning
circuit
core
frequency
inductance
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Robert L Harvey
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RCA Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01FMAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
    • H01F21/00Variable inductances or transformers of the signal type
    • H01F21/02Variable inductances or transformers of the signal type continuously variable, e.g. variometers
    • H01F21/06Variable inductances or transformers of the signal type continuously variable, e.g. variometers by movement of core or part of core relative to the windings as a whole

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  • In--present broadcasting systems it is Adesirable to provide the same degree of selectivity, that is, the same kc. band-width, throughout a given tuning range for signal receiving circuits and the like, in order that Various closely spaced signal channels may be selected without interference, the present separation between signalchannels being at kc. asis well known.
  • an improved variable inductance or permeability tuning system having an inductance winding and a movable tuning core as the variable tuning element in one or more tuned circuits, in which the inductance increasing effect of the core on the winding is less than the resistance increasing effect, whereby the signal to noise ratio through a predetermined tuning range may be substantially constant.
  • variable permeability tuning must vary in approximately the same 3:1 ratio as the ratio of the frequency change over thel said tuning band.
  • the Q of the signal receiving circuits providtem wherein a tuning inductance of the movable core type is provided in each tuned signal conveying circuit for tuning control, having a relatively low cost core material therein providing an improved and predetermined control 'of the variation of the Qof the tuned circuits.
  • Figure l is a schematic circuit diagram of a variable permeability tuning system embodying the invention.
  • Figure 2 is a graph comprising a series of curves illustrating certain operating characteristics of the system of Fig. 1, and
  • Figure 3 is a cross sectional view, on an enlarged scale, of a variable permeability tuning unit for one of the circuits of Fig. 1.
  • a tunable signal conveying circuit comprising a tuning inductance 6 which is varied by means of a suitable movable core element I providing variation in the permea bility of the core area of the inductance 6, and a shunt fixed capacitor 8 for the inductance.
  • the circuit is provided with an AVC connection as indicated at 9 and is connected at the opposite end to the signal input grid II'I of a signal amplifier tube II, which may here be considered as the input or R.
  • ⁇ 'I'l'ie tuned circuit 5 is coupled through a capacitor I2 to a low impedance signal input circuit such as an antenna circuit I3 for supplying signals to the first amplier stage through the tuned circuit 5.
  • 'I'he tube II is provided with a signal output circuit I5 including-the primary Winding I 8 of an interstage coupling transformeril.
  • the secondary Il and a shunt capacitor 20 are included in a tuned circuit I9 similar to the tuned circuit 5 and tunable through the same frequency range by a second movable core element 2l connected for unitary control with the core element 1, as indicated by the dotted connection ⁇ 22.
  • the tuning circuit I is likewise connected with the AVC lead 9 which is bypassed to ground as indicated at 23.
  • the high potential side of the circuit I9 is connected to the signal input grid 24 of a signal mixer or rst detector tube 25.
  • a local source of oscillations represented by an oscillator circuit 28, is connected through a circuit 26 to a second signal input grid 21 of the first detector.
  • the oscillator is preferably also provided with a para magnetic core 30 ganged with the other cores for tuning lto a frequency differing from that of the circuits and I 8 by a constant difference or intermediate frequency.
  • the intermediate frequency is derived from a tuned intermediate frequency output circuit 29.
  • the tuning inductance i, and the tuning inductance I8 provided by the secondary of the transformer I1 are normally high Q solenoid windings preferably of the accumulative type, of Litz wire, and provided with movable core elements 1 and 2i, respectively, which move into and out of the low potential ends, as indicated, to vary the permeability.4 and the tuning 0f the circuits in whichthe inductances are connected through predetermined fref quency ranges.
  • this may be considered to be the broadcast band from 550 to 1500 kc. in each of the circuits 5 and I9, and from 1000 -to 1950 kc. in the oscillator circuit 2l, thereby providing an intermediatel frequency of 450 kc.
  • the selectivity of means, the Q of the circuits must vary with frequency.
  • the Q of a circuit is equal to the reactance divided by the R.-F. resistance and in the case of the inductance tuned circuit shown, equals f' in which Jo 'is the resonance frequency of the circuit, fi is the frequency below resonance at which the signal response is 70.7 percent off resonance and fz is the frequency above resonance at which the response is 70.7 percent off resonance.
  • the Q of the circuit is equal to the resonance frequency divided by the selectivity represented by the effective pass band of the circuit. For example, at 500 kc. with the 70.7 percent selectivity response characteristic 5 kc. wide, the Q of the circuit may be said to be 100, while at 1500 kc., with the same selectivity characteristic, the Q is 300. Thus, with a frequency change of 1:3, it will be seen that for a constant selectivity characteristic, the Q of the circuit must vary in the same proportion of 1:3.
  • the Q at the high frequency end of the tuning range may be of the order of l0, while at the low frequency end of the tuning range it may be of the order of
  • this type of core material tends to vary the IQ of the circuits with y frequency in an opposite manner to that desired the tuning system and the signal to noise ratio are preferably substantially constant throughout the tuning range. and in order to obtain this for maintaining constant selectivity.
  • a tuning inductance and core arrangement may be provided for variable permeability tuning which permits a variation of the ratio of the inductance and damping or resistance changing effects and the Q of the circuit, in proportion to the variation in frequency over the tuning range.
  • the same core material having particles of approximately 100.microns in size in a suitable binder may provide a reduction in the Q at the low frequency end of the tuning range to approximately 15, as compared to 70 at the high frequency end, and that the same results may be obtained with a low grade of Swedish sponge iron, also preferably hydrogen reduced, costing a small fraction of the iron 4referred to.
  • any desired ratio between the inductance and damping or resistance increasing effect of the core and the value of the Q of a circuit may be obtained, and any desired rate of change may be produced with tuning.
  • cores providing substantially constant Q by utilizing 10 parts of the higher grade reduced iron with particles of 10 micron size and 4 parts of low grade sponge iron with particles of micron size.
  • the loss of gain in the R.F. antenna circuit is compensated .by causing the primary I6, coupled to the secondary circuit I9, to resonate in or below the lower frequency end of the tuning range so that the R.F. gain of the primary I6 increases with a decrease in frequency, in accordance with the curve 40, as the circuits are tuned. This compensates for the decrease in the gain of the antenna circuit indicated by the curve 38, thereby providing an overall gain which is substantially constant for the combined tuning system.
  • the inductance increasing effect of' the core is less than the damping or resistance increasing effect as the core enters the inductance windingin each circuit, the cores being so constituted that the desired variation in the Q is obtained, thereby to establish substantially a constant noise to signal ratio and selectivity over the tuning range of the variable permeability tuned circuit in which the inductance winding is provided at the tuning unit.
  • a tuning inductance is shown of the type adapted for use in the antenna or signal input circuit of Fig. 1 andillustrating a modification of the core arrangement.
  • the tuning or inductance winding is indicated at 45 and as hereinbefore referred to, is preferably of the accumulative type and provided with a movable tuning core element 46 which is movable into and out of one end of a ooil'form on which the winding 45 is-supported.
  • the core 46 may be Wholly of' one kind of ferro-magnetic material, such as hydrogen reduced iron, while the lower grade iron, such as sponge iron, may be included in two end rings 48 and 49 surrounding the coil form at the ends of the winding 45 as shown.
  • the core element 46 should be of,sufllcient length vto extend fully through ⁇ and between both rings 48 and 49.
  • the end rings are caused to be increasingly effective to impart the desired resistance and damping to the tuning of the winding.
  • this arrangement somewhat simplifies the process required, for the reason that the core elements may be made of differing materials, the low grade iron being included in the rings and the high grade iron being included in the movable core 46 or the latter may also include a proportion of the lower grade iron, depending upon the characteristic desired.
  • the core may be divided into units, each containing a different proportion of low grade and high grade ferro-magnetic material.
  • the core may be in part of one material or group of materials and in part of another material or group of materials, all of which are effective to control, in the manner described, the relation of the inductance or tuning to the effective resist ance'or damping of the circuit in which the in,- ductance is connected.
  • a tuning inductance winding means providing a movable tuning core element for said inductance winding comprising a molded body of comminuted magnetically permeable material so constituted that the inductance increasing effect of thecore is less than the resistance increasing effect thereof 'as said core is moved into close relation to the inductance, one of the magnetic ingredients of said core being sponge iron in predominating proportion to other ingredients therein comprising hydrogen reduced iron in such relative proportion that variation of the Q of the winding with frequency is reversed from the normal variation, and increases with frequency as the tuning of said winding is increased toward the high frequency end of the tuning range thereof.
  • a tunable radio signal circuit comprising a tuning inductance winding, a capacitor connected in shunt relation thereto, a movable tuning core for said winding containing low grade comminut-v ed iron in pregdominating proportion with high grade comminuted iron such that the Q varies substantially proportionally to the change in frestantially constant over the tuning range of said circuit, and means responsive to frequency variations for compensating the variation of the Q of said circuit to maintain substantially constant signal gain through said system.
  • a tunable radio signal circuit comprising a tuning inductance winding, a capacitor connected in shunt relation thereto, a movable tuning core for said winding comprising a plurality of iinely divided ferro-magnetic materials oi' di'erent resistance changing eiects in predetermined proportion providing'a Q for the circuit which varies substantially proportionally to the change in irequency of the circuit as the core is moved, whereby the selectivity of said circuit is rendered substantially constant over the tuning range of said circuit, and means responsive to frequency variation for compensating the variation of the Q of said circuit to maintain substantially constant signal gain through said system.
  • a tunable radio signal circuit comprising ⁇ a tuning inductance winding, a tuning capacitor connected in shunt relation thereto, and a movable tuning core for said winding comprising finely divided ferro-magnetic material of mixed quality and predetermined proportion providing a Q for the circuit whch varies substantially proportionally to the change in frequency of the circuit as the core is moved, whereby the selectivity of said circuit ⁇ is rendered substantially constant over the tuning range of said circuit, one of the ferromagnetic constituents of said core being sponge iron in predominating proportion to other in- ROBERT L.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Input Circuits Of Receivers And Coupling Of Receivers And Audio Equipment (AREA)

Description

July 5, 1943- Y R. L. HARVEY 2,323,376
VARIABLE PERMEABILITY TUNING SYSTEM Filed April 27, 1940 46 l 49 aw @Mb/.f /Aa/V :inventor Y Gttorng Patented July 6, 1943 UNITED STATES PATENT OFFICE 2,323,376 VARIABLE PERMEABIIJTY TUNING SYSTEM Robert L. Harvey, Collingswood, N. J., assignor to Radio Corporation of America, a corporation of Delaware Application April 27, 1940, Serial No. 331,966
4 Claims. (Cl. Z50-40) kcomprising a solenoid inductance winding provided with a molded cylindrical core of comminuted magnetically permeable material arranged4 to be moved axially into and out of one end of the winding between a position substantially wholly within, to ,a position substantially wholly without, the confines of the winding, thereby varying the permeability of the inductance core area and the frequency response of the tuned circuit of which the inductor forms a part.
In--present broadcasting systems, it is Adesirable to provide the same degree of selectivity, that is, the same kc. band-width, throughout a given tuning range for signal receiving circuits and the like, in order that Various closely spaced signal channels may be selected without interference, the present separation between signalchannels being at kc. asis well known.
In accordance with the present invention, there is provided an improved variable inductance or permeability tuning system having an inductance winding and a movable tuning core as the variable tuning element in one or more tuned circuits, in which the inductance increasing effect of the core on the winding is less than the resistance increasing effect, whereby the signal to noise ratio through a predetermined tuning range may be substantially constant. y'
It is an object of the invention to provide a tuning system of the character referred to in which the gain and/or signal to noise ratio, while tuning over a predetermined frequency band, is
ed with variable permeability tuning must vary in approximately the same 3:1 ratio as the ratio of the frequency change over thel said tuning band.
It ls, therefore, also an object of the present invention to provide an improved variable permeability tuning system wherein the Q of the tuned circuits. may be made to vary in a predetermined manner with frequency variation in tuning, to provide a predetermined or substantially constant selectivity over the tuning band as hereinbefore referred to.`
They signal input circuit of a radio signal re ceiving system isnormally coupled to a low impedance signal supply circuit, such as that provided by an antenna or signal collector, in which the gain is proportional to the Q of the input circuit. Accordingly, it is a further object of the present invention to provide an improved variable permeability tuning system wherein the signal input circuit may be coupled to a low impedance source and tuned over a predetermined range, while maintaining the overall gain of the tuning system substantially constant, although the gain `in the input circuit varies in proportion to the variation in the Q of the input circuit.
It is also an object of the present invention to lprovide an improved permeability'tuning syshigh and substantially constant, whereby itis y quency. In tuning from 1500 to 550 kc., therefore, in the present broadcast band, for example, the Q of the signal receiving circuits providtem wherein a tuning inductance of the movable core type is provided in each tuned signal conveying circuit for tuning control, having a relatively low cost core material therein providing an improved and predetermined control 'of the variation of the Qof the tuned circuits.
It is also a further object of the present invention to provide an improved variable permeability radio tuning system involving a plurality `of signal conveying circuits having variable incluctancel tuning elements therein, 'including movable tuning cores providing a Q in each circuit which varies with tuning proportional to the frequency, thereby providing -ai uniform selectivityover a predetermined tuning band, and means in at least one of said circuits for altering the vgain therein in a predetermined manner, thereby to compensate for gain variation with tuning in another of said circuits.
The invention will, however, be further understood from the following description when considered in connection with the accompanying drawing, and its scope is pointed out in the appended claims.
l In the drawing,
Figure l is a schematic circuit diagram of a variable permeability tuning system embodying the invention,
Figure 2 is a graph comprising a series of curves illustrating certain operating characteristics of the system of Fig. 1, and
Figure 3 is a cross sectional view, on an enlarged scale, of a variable permeability tuning unit for one of the circuits of Fig. 1.
Referring to Fig. 1, 5 is a tunable signal conveying circuit comprising a tuning inductance 6 which is varied by means of a suitable movable core element I providing variation in the permea bility of the core area of the inductance 6, and a shunt fixed capacitor 8 for the inductance. The circuit is provided with an AVC connection as indicated at 9 and is connected at the opposite end to the signal input grid II'I of a signal amplifier tube II, which may here be considered as the input or R. F. amplier stage of a superheterodyne radio signal receiving system.
`'I'l'ie tuned circuit 5 is coupled through a capacitor I2 to a low impedance signal input circuit such as an antenna circuit I3 for supplying signals to the first amplier stage through the tuned circuit 5.
'I'he tube II is provided with a signal output circuit I5 including-the primary Winding I 8 of an interstage coupling transformeril. The secondary Il and a shunt capacitor 20 are included in a tuned circuit I9 similar to the tuned circuit 5 and tunable through the same frequency range by a second movable core element 2l connected for unitary control with the core element 1, as indicated by the dotted connection `22. The tuning circuit I is likewise connected with the AVC lead 9 which is bypassed to ground as indicated at 23. The high potential side of the circuit I9 is connected to the signal input grid 24 of a signal mixer or rst detector tube 25. A local source of oscillations, represented by an oscillator circuit 28, is connected through a circuit 26 to a second signal input grid 21 of the first detector. The oscillator is preferably also provided with a para magnetic core 30 ganged with the other cores for tuning lto a frequency differing from that of the circuits and I 8 by a constant difference or intermediate frequency. The intermediate frequency is derived from a tuned intermediate frequency output circuit 29. l
While the invention is described in connection with the R.F. and iirst detector circuits oi' a superheterodyne receiver, it may =be applied to any signal conveying channel wherein a series of tunable signal circuits are provided in cascade. In the present example, the tuning inductance i, and the tuning inductance I8 provided by the secondary of the transformer I1 are normally high Q solenoid windings preferably of the accumulative type, of Litz wire, and provided with movable core elements 1 and 2i, respectively, which move into and out of the low potential ends, as indicated, to vary the permeability.4 and the tuning 0f the circuits in whichthe inductances are connected through predetermined fref quency ranges. In the present example, this may be considered to be the broadcast band from 550 to 1500 kc. in each of the circuits 5 and I9, and from 1000 -to 1950 kc. in the oscillator circuit 2l, thereby providing an intermediatel frequency of 450 kc.
As hereinbefore referred to, the selectivity of means, the Q of the circuits must vary with frequency. i
As is known. the Q of a circuit is equal to the reactance divided by the R.-F. resistance and in the case of the inductance tuned circuit shown, equals f' in which Jo 'is the resonance frequency of the circuit, fi is the frequency below resonance at which the signal response is 70.7 percent off resonance and fz is the frequency above resonance at which the response is 70.7 percent off resonance. In other words, the Q of the circuit, as herein considered, is equal to the resonance frequency divided by the selectivity represented by the effective pass band of the circuit. For example, at 500 kc. with the 70.7 percent selectivity response characteristic 5 kc. wide, the Q of the circuit may be said to be 100, while at 1500 kc., with the same selectivity characteristic, the Q is 300. Thus, with a frequency change of 1:3, it will be seen that for a constant selectivity characteristic, the Q of the circuit must vary in the same proportion of 1:3.
Utilizing hydrogen reduced iron as disclosed, for example, in the patent to Speed 1,274,952, comprising s mall particles of the size of 10 microns in a suitable insulating binder for the cores 'I and 2|, the Q at the high frequency end of the tuning range may be of the order of l0, while at the low frequency end of the tuning range it may be of the order of |50. Thus, in addition to being relatively costly, this type of core material tends to vary the IQ of the circuits with y frequency in an opposite manner to that desired the tuning system and the signal to noise ratio are preferably substantially constant throughout the tuning range. and in order to obtain this for maintaining constant selectivity.
However. a tuning inductance and core arrangement may be provided for variable permeability tuning which permits a variation of the ratio of the inductance and damping or resistance changing effects and the Q of the circuit, in proportion to the variation in frequency over the tuning range. In this connection. it has been found that the same core material having particles of approximately 100.microns in size in a suitable binder may provide a reduction in the Q at the low frequency end of the tuning range to approximately 15, as compared to 70 at the high frequency end, and that the same results may be obtained with a low grade of Swedish sponge iron, also preferably hydrogen reduced, costing a small fraction of the iron 4referred to.
By suitably proportioning the higher grade reduced iron and the cheaper sponge iron, any desired ratio between the inductance and damping or resistance increasing effect of the core and the value of the Q of a circuit may be obtained, and any desired rate of change may be produced with tuning. For example, at present it has been found possible to produce cores providing substantially constant Q by utilizing 10 parts of the higher grade reduced iron with particles of 10 micron size and 4 parts of low grade sponge iron with particles of micron size.
For use in the circuit shown, to provide a variacharacteristic with variable permeability tuning 1| tion of Q in a 3:1 ratio in tuning through the range from 1500 to 500 kc., approximately 9 parts of low grade sponge iron with parl/cles of 100 micron size are combined with one part of the higher grade reduced iron with particles of micron size in Aa suitable insulating binder.
This has been found to provide a Q-of 70 at the high frequency end of the tuning range and a Q of approximately 23 at the low frequency end, thereby complying with the desired ratio of 3:1
in conformance with the change in frequency l' circuit with a low impedance input circuit such as that provided by the antennav system I3. v"llhe R.-F. gain of the secondary circuit I9, however, remains substantially constant throughout the tuning range with variation of Q as indicated by 'the curve 38. The curves vabove referred 4to are slightly displaced, particularly curves 36--31-39, to indicate the response of the. circuits more effectively.
The foregoing will be seen more clearly from a `consideration of the fact that the gain at 500 kc. equals the gain at 1500 kc. as shown below:
To provide substantially a constant gain and signal to noise ratio-,'as well as constant selectivity, the loss of gain in the R.F. antenna circuit is compensated .by causing the primary I6, coupled to the secondary circuit I9, to resonate in or below the lower frequency end of the tuning range so that the R.F. gain of the primary I6 increases with a decrease in frequency, in accordance with the curve 40, as the circuits are tuned. This compensates for the decrease in the gain of the antenna circuit indicated by the curve 38, thereby providing an overall gain which is substantially constant for the combined tuning system.
Furthermore, as the Q decreases with frequency in tuning, it is evident that the inductance increasing effect of' the core is less than the damping or resistance increasing effect as the core enters the inductance windingin each circuit, the cores being so constituted that the desired variation in the Q is obtained, thereby to establish substantially a constant noise to signal ratio and selectivity over the tuning range of the variable permeability tuned circuit in which the inductance winding is provided at the tuning unit.
Referring now to Fig. 3, a tuning inductance is shown of the type adapted for use in the antenna or signal input circuit of Fig. 1 andillustrating a modification of the core arrangement. The tuning or inductance winding is indicated at 45 and as hereinbefore referred to, is preferably of the accumulative type and provided with a movable tuning core element 46 which is movable into and out of one end of a ooil'form on which the winding 45 is-supported. In the present example, however, the core 46 may be Wholly of' one kind of ferro-magnetic material, such as hydrogen reduced iron, while the lower grade iron, such as sponge iron, may be included in two end rings 48 and 49 surrounding the coil form at the ends of the winding 45 as shown.
With this arrangement, as the coil element 46 is moved into the winding fully it lies within the end rings and establishes a magnetic circuit throughv them whereby their resistance 'and damping increasing effect is imparted to the winding and the circuit in which it is used, to cause a reduction in the Q of the circuit as before described with the composite core, in which all of the core material is placed in the movable core element.
In the form shown in Fig. 3, the core element 46 should be of,sufllcient length vto extend fully through` and between both rings 48 and 49. Thus, as the core 46 is moved into the winding 45 the end rings are caused to be increasingly effective to impart the desired resistance and damping to the tuning of the winding.
In manufacturing, this arrangement somewhat simplifies the process required, for the reason that the core elements may be made of differing materials, the low grade iron being included in the rings and the high grade iron being included in the movable core 46 or the latter may also include a proportion of the lower grade iron, depending upon the characteristic desired.
With the core element 46 withdrawn from the high frequency position, the rings are not effective to damp or change the resistance of the Winding to any appreciable degree. Thus, it'will be seen that the core may be divided into units, each containing a different proportion of low grade and high grade ferro-magnetic material. The core may be in part of one material or group of materials and in part of another material or group of materials, all of which are effective to control, in the manner described, the relation of the inductance or tuning to the effective resist ance'or damping of the circuit in which the in,- ductance is connected.
I claim as my inventionz- 1. In a variable permeability tuning system for radio signal circuits, the combination of a tuning inductance winding, means providing a movable tuning core element for said inductance winding comprising a molded body of comminuted magnetically permeable material so constituted that the inductance increasing effect of thecore is less than the resistance increasing effect thereof 'as said core is moved into close relation to the inductance, one of the magnetic ingredients of said core being sponge iron in predominating proportion to other ingredients therein comprising hydrogen reduced iron in such relative proportion that variation of the Q of the winding with frequency is reversed from the normal variation, and increases with frequency as the tuning of said winding is increased toward the high frequency end of the tuning range thereof.
2. In a variable permeability tuning system, a tunable radio signal circuit comprising a tuning inductance winding, a capacitor connected in shunt relation thereto, a movable tuning core for said winding containing low grade comminut-v ed iron in pregdominating proportion with high grade comminuted iron such that the Q varies substantially proportionally to the change in frestantially constant over the tuning range of said circuit, and means responsive to frequency variations for compensating the variation of the Q of said circuit to maintain substantially constant signal gain through said system.
3. In a variable permeability tuning system, a tunable radio signal circuit comprising a tuning inductance winding, a capacitor connected in shunt relation thereto, a movable tuning core for said winding comprising a plurality of iinely divided ferro-magnetic materials oi' di'erent resistance changing eiects in predetermined proportion providing'a Q for the circuit which varies substantially proportionally to the change in irequency of the circuit as the core is moved, whereby the selectivity of said circuit is rendered substantially constant over the tuning range of said circuit, and means responsive to frequency variation for compensating the variation of the Q of said circuit to maintain substantially constant signal gain through said system. Y
15 Zredients therein.
4. In a variable permeability tuning system, a tunable radio signal circuit comprising `a tuning inductance winding, a tuning capacitor connected in shunt relation thereto, and a movable tuning core for said winding comprising finely divided ferro-magnetic material of mixed quality and predetermined proportion providing a Q for the circuit whch varies substantially proportionally to the change in frequency of the circuit as the core is moved, whereby the selectivity of said circuit`is rendered substantially constant over the tuning range of said circuit, one of the ferromagnetic constituents of said core being sponge iron in predominating proportion to other in- ROBERT L. HARVEY.
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Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2422134A (en) * 1943-03-29 1947-06-10 Rca Corp Distance indicator
US2509425A (en) * 1946-10-29 1950-05-30 Mallory & Co Inc P R Iron core variometer
US2555511A (en) * 1946-04-09 1951-06-05 Rca Corp Variable permeability tuning system
US2626318A (en) * 1947-10-04 1953-01-20 Rca Corp Radio-frequency transformer and inductance element therefor
US2668908A (en) * 1945-09-19 1954-02-09 Elvin E Herman Panoramic receiver bandpass compensation system
US2871345A (en) * 1953-03-25 1959-01-27 Radio Receptor Company Inc Ultra high frequency tuners or converters
US2957124A (en) * 1956-11-26 1960-10-18 Aeronautical Comm Equipment In High frequency choke coil
US3295055A (en) * 1961-04-20 1966-12-27 Tdk Electronics Co Ltd Combined unit of impedance
US3947787A (en) * 1974-12-26 1976-03-30 Oak Industries Inc. Mechanical TV control unit

Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2422134A (en) * 1943-03-29 1947-06-10 Rca Corp Distance indicator
US2668908A (en) * 1945-09-19 1954-02-09 Elvin E Herman Panoramic receiver bandpass compensation system
US2555511A (en) * 1946-04-09 1951-06-05 Rca Corp Variable permeability tuning system
US2509425A (en) * 1946-10-29 1950-05-30 Mallory & Co Inc P R Iron core variometer
US2626318A (en) * 1947-10-04 1953-01-20 Rca Corp Radio-frequency transformer and inductance element therefor
US2871345A (en) * 1953-03-25 1959-01-27 Radio Receptor Company Inc Ultra high frequency tuners or converters
US2957124A (en) * 1956-11-26 1960-10-18 Aeronautical Comm Equipment In High frequency choke coil
US3295055A (en) * 1961-04-20 1966-12-27 Tdk Electronics Co Ltd Combined unit of impedance
US3947787A (en) * 1974-12-26 1976-03-30 Oak Industries Inc. Mechanical TV control unit

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