US2636986A - Television antenna - Google Patents

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US2636986A
US2636986A US2636986DA US2636986A US 2636986 A US2636986 A US 2636986A US 2636986D A US2636986D A US 2636986DA US 2636986 A US2636986 A US 2636986A
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coils
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television
antennas
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q9/00Electrically-short antennas having dimensions not more than twice the operating wavelength and consisting of conductive active radiating elements
    • H01Q9/04Resonant antennas
    • H01Q9/06Details
    • H01Q9/14Length of element or elements adjustable
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/36Structural form of radiating elements, e.g. cone, spiral, umbrella; Particular materials used therewith
    • H01Q1/362Structural form of radiating elements, e.g. cone, spiral, umbrella; Particular materials used therewith for broadside radiating helical antennas

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  • This invention relates generally to antennas for the reception or transmission of electrical radiation and more particularly is concerned with antennas for the reception of high frequency broad. band radiation, such as for example, television.
  • Present day television is broadcast at high frequencies in two general bands, one of which is from 44 to 88 megacycles per second, and the second of which is from 1'74 to 216 megacycles per second.
  • the video frequency electric waves which are transmitted for reception are considerably shorter" than ordinary radio waves.
  • the long antennas of radio are therefore neither suitable nor.desirable in television.
  • frequencies of the order of 40 to 200 megacycles are to be received or transmitted, the amount of energy which can be radiated or received by a given antenna is wery small, and hence it is essential that such antennas be directive.
  • the basic antenna for greatest efficiency which may be considered an element, since most'antennas are made up of such basic antennas, is a di-pole, or half-wave antenna.
  • such an antenna is constructed of a conductor half a wave long. This electrical length is slightly less than the physical length, and gives rise to current andvoltage distribution which is best for reception and transmission of high frequency energy. The existence of this condition gives rise to a resonance in the antenna so that at the center thereof, to which the lead-in transmission line is usually secured, there is a maximum of current and a minimum of voltage, and the impedance of the antenna is practically pure resistance.
  • an antenna designed for best reception at the low end of the lower band would be of the order of eleven feet in length; at the high end of the'lower band would be of the order of five and one-half feet in length; at the low end of the upper band would be of the order of 2.8 feet in length; and at the high end of the higher band would be of the order of 2.2 feet in length.
  • Two compromises must be made in order to construct a television antenna which is suitable for reception over the entire range of both bands.
  • One compromise must be made in each band in order to choose a length which will be capable of receiving all of the channels in that band, and then an overall compromise must be made so that the antenna will receive stations from both bands.
  • the net result has been that the common television antenna is of the order of three to six feet in length.
  • a second type of antenna is one which has two sections, one for receiving in each of the present day bands. In the event that there is an increase in allotted bands of the spectrum, another section will have to be added to this antenna.
  • An important object of my invention is to provide a single antenna, capable of being tuned to any frequency over a wide range including present day television bands.
  • a further object of my invention is to provide an antenna which is capable of highly'eflicient reception by reason of the fact that the effective length thereof can readily be adjusted to the frequency of the video signal being received over the entire television frequency spectrum.
  • a further object of my invention is to provide a construction of television antenna which is highly eiiicient and yet so small in physical size that it is readily portable, can be installed indoors and in addition is extremely economical to manufacture.
  • My invention has given rise to many advantages over prior television antennas. It has eliminated the need for expensive outdoor weatherproof installations. Zt has eliminated the expense of maintenance of such outdoor antennas. It has eliminated the need for long transmission lines from the antenna to the receiver. It has enabled the antenna, by reason of its being immediately adjacent the receiver, to be made revolvable so that the maximum directional response can be obtained merely by manual orientation of the antenna. Obviously, rooftop antennas cannot be made revolvable without the use of highly expensive equipment.
  • My new antenna can be placed immediately adjacent the receiving equipment and can be constructed so that it is ornamental in appearance so as not to detract from the esthetic effect of the furnishings in a given room.
  • the elimination of long lengths of transmission line by reason or" the location of my new antenna makes better reception possible.
  • standing waves are set up which give rise to blurring of the video picture, and sometimes to ghosts.
  • transmissions lines to be of the order of inches in length. Short transmission lines also decrease loss of signal due to attenuation, and decrease noise pick-up In the case of television installations where the antenna is a substantial distance from the receiving equipment, there may exist a phase difference between the signal received directly at the receiver and that received from the antenna via the transmission line, giving rise of blurring or ghosts. This fault can be corrected by shielding the receiver, an expedient unnecessary in case my new antenna is used.
  • Certain objects of my invention lie in the provision of an antenna whose electrical length isconsiderably greater than its physical length; to provide a broad band antenna for indoor use;
  • Fig. 1 is a perspective view of an antenna embodying my new invention.
  • Fig. 2 is a top plan view of the same.
  • Fig. 3 is a side elevational view of the antenna.
  • Fig. 4 is an end elevational View of the antenna.
  • Fig. 5 is a fragmentary sectional view through the antenna taken along the axis of the antenna di-pole as indicated by the line 5-5 of Fig. 3 and in the indicated direction, and showing the details of construction of the antenna coil.
  • Fig. 6 is a sectional view throughthe antenna di-pole along the axis thereof as indicated by line 6-5 of Fig. 3, in the direction indicated.
  • Fig. 7 is a sectional view taken along the line 'E-l of Fig. 2 and in the indicated direction.
  • Fig. 8 is a top plan view of a modified form antenna embodying my invention.
  • an antenna a part of which consists of a tubular conductor, preferably circular in cross-section although not limited thereto, having a second part formed of a telescoping member of slightly lesser cross section, but having a coil of bare wire wound thereon.
  • the coil form is of some material having high dielectric strength, and the winding is laid on the form, preferably in grooves, so that it extends out of the grooves, and engages the inner surface of the tubular conductor whereever the form is telescoped therein.
  • the windings are spaced apart in order to distribute the inductance along the form and to provide a wide area capable of cutting the incident video waves.
  • My preferred embodiment includes a di-pole having two tubular central sections arranged with their axes aligned and their ends spaced and connected to the lead-in transmission line, and having coils telescoped into the free ends thereof.
  • a modified form has the central portion of the di-pole formed of coils, while the ends of the coils are capped with telescoping cylindrical sleeves.
  • the reference character it! designates generally a platform which may comprise a fixed member, the top of a receiving equipment, a. table, or the like, and is not. necessarily circular in formation as shown in the drawings.
  • Mounted upon. the platform. [iii II have provided a turntable l l separated from. the platformv ill by a suitable bearing member or washer. l2 and pivoted thereto by means of a. bushing [3 (see Fig- 7.) having. a. flanged upper end as shown. at i l overlying. the turntable. I. i'. This construction enables theturntable. to. be rotated although. same can be lifted upwardly carrying. the bushing 43 therewith. If
  • the bushing l3 may have its lower end peened over and against the bottom of the platform Ill whereby permanently to associate same therewith and prevent removal of the turntable.
  • an insulating member l5 cylindrical in formation, and having a bore l6 through which the transmission line I! is adapted to pass.
  • di-pole antenna designated generally I8
  • parasitic antenna designated generally l9. Both of these antennas are adjustable as to their physical length, and the distance therebetween is also adjustable as will be described.
  • the di-pole antenna consists of a pair of thinwalled tubes ZEI and 2
  • are firmly mounted upon stand-off insulators 23 and 24 formed of some material having very high dielectric strength, such as for example polystyrene, or methyl methacrylate resin. These insulators 23 and 24 are in turn mounted upon the turntable I by means of screws 25 which are engaged into the bottoms of the stand-off insulators through slots 26 and 21 for a purpose presently to be described.
  • upon tr. e insulators 23 and 24 may consist of any suitable fasteners such as for example the bolts shown at 28 and 29 which I have welded to the bottoms oi. the tubes 20 and 2
  • Telescopically mounted within the tubes 20 an :1 2
  • These coils consist of relatively heavy diameter wire 32 wound upon tubular forms 33 of polystyrene or similar insulating material.
  • the wire 32 is laid in spiral grooves 34 cut in the surface of the forms, the depth of the grooves 34 being such that the turns of the wire 32 protrude slightly therefrom, and hence rise above the exterior surface 35 of the forms 33.
  • are identical, hence the description of coil 30 illustrated in Fig. 5 should suflice.
  • the ends of the wire 32 are inserted through openings 36 formed in each end of each form 33 and bent under as shown at 31 on the interior of each form in order to hold the windings in place.
  • outside diameter ofthe coils comprising the outi ermost surface of the windings will engage the inner surface of the tubes 20 and 2
  • are provided with contacts at 38 and 39 adapted to be connected respectively to the wires of the transmission line H.
  • the line I! should have animpedance matching that of the antenna.
  • provide inductance, and by arranging the coils so that their axes are aligned with those of the tubes 20 and 2
  • the efficiency of such an antenna is greater than a short antenna having lumped inductive loading because the coils 30 and 3
  • the antenna illustrated utilizes cylindrical tubes having a diameter of approximately two inches, whereby the antenna can receive broad band of frequencies without the discrimination against any portion of a channel.
  • the effect accompanying such construction is a reduction of signal pick-up from the incident waves, but the coils 30 and 3
  • of my antenna are capable of being moved in and out of the tubes 20 and'2l by the observer.
  • the turns of the coils that are enclosed within the tubes are short circuited since the wire 32 thereof is in engagement with the inner surface of the said tubes.
  • This not only decreases the physical length of the di-pole antenna that cuts the video waves, but as well decreases the inductance of the coils 30 and 3
  • the antenna is readily tunable, but it is readily tunable over an extremely wide range of frequencies so that it i its simple matter to tune the antenna to any station in the presently used television bands.
  • This dimension is not critical, however, especially in the case of broad band reception where the thickness of the antenna proper is of the order of that dimension, and hence adjustment between the parasitic and dipole antennas may be eliminated, or the antenna may be adjusted for best reception over the entire band, and then fixed.
  • the parasitic antenna consists of a fixed central tube 59 mounted upon a standoff insulator 5i and having telescoping tubes 52 and 53 on the ends thereof. This provides for tuning of the parasitic antenna i9. This type of parasitic antenna acts as a reflector, serving to pick up additional energy from the passing video waves and reflect at proper phase into the dipole It.
  • the coils 3i) and 31 are not directly connected. to the transmission line [1. They are each produced as a unit and then telescoped into respective tubes 2c and 2!. enables shipping the antenna in a small container.
  • Fig. 8 I have shown a modification of my invention which reverses the positions of the coils and tubes of the antenna heretofore described.
  • the efiiciency of such antenna and the advantages are generally the same asv those of the antenna described.
  • the tubes 20 and 2! are formed as sleeves so and 6! which slide over the ends of the coils 62 and 83 respectively.
  • the coils are both mounted upon a single form E l which is attached to the turntable H, and each has its inner terminus connected with the transmission line ii as shown at 65 and 6B. In all other respects the device is the same as described and is turnable in the same manner.
  • the parasitic antenna has been shown This constructed from tubing it should be obvious that same could also be formed of coils and tubes in the same manner as I form my di-poles.
  • various combinations of coils and tubes could be arranged in the form of a folded dipole to provide increased antenna impedance.
  • a broad band television receiving antenna comprising horizontally arranged driven and parasitic elements spaced one in back of the other with their axes parallel and both perpendicular to the direction of the incident waves, the driven element comprising a pair of hollow metallic cylindrical tubes with a common axis, spaced one from the other along the axis and rigidly supported in such spaced position, a rotatable standard mounting said tubes, lead-in means electrically connected to said tubes to transmit the signal received when same are resonating as the halves of a dipole, each tube having a telescoping member in the outer end thereof, said member being formed of insulating material and having Wire helically arranged on the exterior thereof so that as the member is moved in and out of the respective tube, the tube will short circuit or uncover turns to tune the dipole, said parasitic element being a hollow cylindrical metal tube electrically continuous along its length secured to said standard and insulated therefrom.

Description

April 8, 1953 R. VRIDERMAN 2,636,986
TELEVISION ANTENNA Filed Oct. 11. 1948 2 SHEETS-SHEET 1 5 jmmnzm J 25 @alj/MV/Ildil ow- Slams April 8, 1953 R. RIDERMAN 2,636,986
TELEVISION ANTENNA Filed Oct. 11. 1948 2 SHEETS-SHEET 2 3 WZbI/VMJ Patented Apr. 28, 1953 TELEVISION ANTENNA Rudolph Riderman, Chicago, Ill., assignor, by mesne assignments, to Fred Gold, Chicago, Ill.
Application October 11, 1948, Serial No. 53,800
2 Claims. 1
This invention relates generally to antennas for the reception or transmission of electrical radiation and more particularly is concerned with antennas for the reception of high frequency broad. band radiation, such as for example, television.
It is known that an efiicient transmitting antenna will likewise be a satisfactory receiving antenna and vice-versa, hence, although my new antenna is primarily intended for reception it is nevertheless capable of being utilized for the transmission of television.
Present day television is broadcast at high frequencies in two general bands, one of which is from 44 to 88 megacycles per second, and the second of which is from 1'74 to 216 megacycles per second. For any given metropolitan area, there are channels in both of these bands, and therefore it is essential that an antenna be capable of receiving the video waves from transmitting stations operating in both bands.
.All of the antennas used for the reception of video waves have heretofore been constructed in manners giving rise to objections which have considerably delayed the popularity of television, and hence limited sales of reception equipment and the scope of the benefits to be derived from wide-spread use of television. It is the principal object of my invention to attain the broad result of increased public recognition and acceptance of television by making it more economical, convenient, and desirable for the consumer to obtain, install, use, and enjoy a television receiving equipment.
The video frequency electric waves which are transmitted for reception are considerably shorter" than ordinary radio waves. The long antennas of radio are therefore neither suitable nor.desirable in television. When frequencies of the order of 40 to 200 megacycles are to be received or transmitted, the amount of energy which can be radiated or received by a given antenna is wery small, and hence it is essential that such antennas be directive. In addition, it is also desirable to utilize the best attributes of an antenna in order to enable the maximum energy to be transferred thereby, either from the transmitter to the ether, or from the ether to the receiver. The basic antenna for greatest efficiency, which may be considered an element, since most'antennas are made up of such basic antennas, is a di-pole, or half-wave antenna. As its name implies, such an antenna is constructed of a conductor half a wave long. This electrical length is slightly less than the physical length, and gives rise to current andvoltage distribution which is best for reception and transmission of high frequency energy. The existence of this condition gives rise to a resonance in the antenna so that at the center thereof, to which the lead-in transmission line is usually secured, there is a maximum of current and a minimum of voltage, and the impedance of the antenna is practically pure resistance.
Considering the frequencies of the bands now being used for television, an antenna designed for best reception at the low end of the lower band would be of the order of eleven feet in length; at the high end of the'lower band would be of the order of five and one-half feet in length; at the low end of the upper band would be of the order of 2.8 feet in length; and at the high end of the higher band would be of the order of 2.2 feet in length. Two compromises must be made in order to construct a television antenna which is suitable for reception over the entire range of both bands. One compromise must be made in each band in order to choose a length which will be capable of receiving all of the channels in that band, and then an overall compromise must be made so that the antenna will receive stations from both bands. The net result has been that the common television antenna is of the order of three to six feet in length.
A second type of antenna is one which has two sections, one for receiving in each of the present day bands. In the event that there is an increase in allotted bands of the spectrum, another section will have to be added to this antenna.
An important object of my invention is to provide a single antenna, capable of being tuned to any frequency over a wide range including present day television bands.
A further object of my invention is to provide an antenna which is capable of highly'eflicient reception by reason of the fact that the effective length thereof can readily be adjusted to the frequency of the video signal being received over the entire television frequency spectrum.
In order to achieve the maximum of eificiency it is best to install an antenna as high above ground as possible, hence television antennas are customarily installed on rooftops and towers. In addition, the size of prior antennas makes it impractical to install same indoors. In crowded communities there is objection to the installation of such antennas, whereby a tenant in an apartment building is deprived of the benefits of television because he is not permitted to install an antenna upon the roof.
A further object of my invention is to provide a construction of television antenna which is highly eiiicient and yet so small in physical size that it is readily portable, can be installed indoors and in addition is extremely economical to manufacture.
My invention has given rise to many advantages over prior television antennas. It has eliminated the need for expensive outdoor weatherproof installations. Zt has eliminated the expense of maintenance of such outdoor antennas. It has eliminated the need for long transmission lines from the antenna to the receiver. It has enabled the antenna, by reason of its being immediately adjacent the receiver, to be made revolvable so that the maximum directional response can be obtained merely by manual orientation of the antenna. Obviously, rooftop antennas cannot be made revolvable without the use of highly expensive equipment.
My new antenna can be placed immediately adjacent the receiving equipment and can be constructed so that it is ornamental in appearance so as not to detract from the esthetic effect of the furnishings in a given room. The elimination of long lengths of transmission line by reason or" the location of my new antenna makes better reception possible. In cases where the line is not perfectly matched to the antenna, standing waves are set up which give rise to blurring of the video picture, and sometimes to ghosts.
The shorter the transmission line, the less is the effect of these standing waves. My invention enables transmissions lines to be of the order of inches in length. Short transmission lines also decrease loss of signal due to attenuation, and decrease noise pick-up In the case of television installations where the antenna is a substantial distance from the receiving equipment, there may exist a phase difference between the signal received directly at the receiver and that received from the antenna via the transmission line, giving rise of blurring or ghosts. This fault can be corrected by shielding the receiver, an expedient unnecessary in case my new antenna is used.
Certain objects of my invention lie in the provision of an antenna whose electrical length isconsiderably greater than its physical length; to provide a broad band antenna for indoor use;
to provide an antenna in which inductive reactance for loading the antenna. is distributed along the same; to provide an antenna in which the inductive reactance is capable of readily being varied; tov provide an antenna having, an inductive. reactance. coil associated therewith in. such a manner that telescopically moving same with respect to another portion of the antenna will vary the inductive effect of such. coil; to provide an antenna which can readily be adjusted. for optimum tuning. and matching.
With the foregoing: and. other objects in. View which will appear as the description proceeds. the invention consists of. certain novel. features of construction, arrangement and a combination of. parts hereinafter fully described, illustrated. in. the accompanying drawings, and particularly pointed out in. the appended claims, it being. un-- derstood that various changes. in the form,v proportion, size and minor details.- of the structure may bev made without. departing from. the. spirit or sacrificing any of the advantages. of! the invention- For the purpose. of facilitating an. understand-- ing of this invention, there is. illustrated in the. accompanying drawings. a preferred embodiment thereof, from an inspection of which, when considered in connection with the following description, this invention, its mode of construction, assembly and operation, and many of its advan tages should be readily understood and appreciated.
Referring to the drawings in which the same characters of reference are employed to indicate correspondence or similar parts throughout the several figures of the drawings:
Fig. 1 is a perspective view of an antenna embodying my new invention.
Fig. 2 is a top plan view of the same.
Fig. 3 is a side elevational view of the antenna.
Fig. 4 is an end elevational View of the antenna.
Fig. 5 is a fragmentary sectional view through the antenna taken along the axis of the antenna di-pole as indicated by the line 5-5 of Fig. 3 and in the indicated direction, and showing the details of construction of the antenna coil.
Fig. 6 is a sectional view throughthe antenna di-pole along the axis thereof as indicated by line 6-5 of Fig. 3, in the direction indicated.
Fig. 7 is a sectional view taken along the line 'E-l of Fig. 2 and in the indicated direction.
Fig. 8 is a top plan view of a modified form antenna embodying my invention.
For carrying out my invention I have provided an antenna, a part of which consists of a tubular conductor, preferably circular in cross-section although not limited thereto, having a second part formed of a telescoping member of slightly lesser cross section, but having a coil of bare wire wound thereon. The coil form is of some material having high dielectric strength, and the winding is laid on the form, preferably in grooves, so that it extends out of the grooves, and engages the inner surface of the tubular conductor whereever the form is telescoped therein. The windings are spaced apart in order to distribute the inductance along the form and to provide a wide area capable of cutting the incident video waves. In this manner I am enabled to increase the eiiective or eiectrical length of my antenna by adding inductive reactance thereto, but in addition I have distributed the coiled conductor along the coil formed thereby increasing the amount of energy the antenna is capable of extracting from the transmitted video wave.
My preferred embodiment includes a di-pole having two tubular central sections arranged with their axes aligned and their ends spaced and connected to the lead-in transmission line, and having coils telescoped into the free ends thereof. A modified form has the central portion of the di-pole formed of coils, while the ends of the coils are capped with telescoping cylindrical sleeves.
For any given frequency, I adjust the antenna for maximum signal and best matching of trans mission line impedance by telescopically moving the coils and tubes relative to one another.
The reference character it! designates generally a platform which may comprise a fixed member, the top of a receiving equipment, a. table, or the like, and is not. necessarily circular in formation as shown in the drawings. Mounted upon. the platform. [iii II have provided a turntable l l separated from. the platformv ill by a suitable bearing member or washer. l2 and pivoted thereto by means of a. bushing [3 (see Fig- 7.) having. a. flanged upper end as shown. at i l overlying. the turntable. I. i'. This construction enables theturntable. to. be rotated although. same can be lifted upwardly carrying. the bushing 43 therewith. If
desired the bushing l3 may have its lower end peened over and against the bottom of the platform Ill whereby permanently to associate same therewith and prevent removal of the turntable.
Centrally of the bushing there is provided an insulating member l5 cylindrical in formation, and having a bore l6 through which the transmission line I! is adapted to pass.
Mounted upon the turntable II I provide a di-pole antenna designated generally I8, and a parasitic antenna designated generally l9. Both of these antennas are adjustable as to their physical length, and the distance therebetween is also adjustable as will be described.
The di-pole antenna consists of a pair of thinwalled tubes ZEI and 2| arranged with their ends juxtaposed and their axes aligned. There is a space 22 between the ends whereby the tubes and 2| do not touch.
The tubes 26 and 2| are firmly mounted upon stand- off insulators 23 and 24 formed of some material having very high dielectric strength, such as for example polystyrene, or methyl methacrylate resin. These insulators 23 and 24 are in turn mounted upon the turntable I by means of screws 25 which are engaged into the bottoms of the stand-off insulators through slots 26 and 21 for a purpose presently to be described. The means for mounting the tubes 20 and 2| upon tr. e insulators 23 and 24 may consist of any suitable fasteners such as for example the bolts shown at 28 and 29 which I have welded to the bottoms oi. the tubes 20 and 2| respectively.
Telescopically mounted within the tubes 20 an :1 2| I provide the coils 30 and 3| respectively. These coils consist of relatively heavy diameter wire 32 wound upon tubular forms 33 of polystyrene or similar insulating material. In the embodiment shown, the wire 32 is laid in spiral grooves 34 cut in the surface of the forms, the depth of the grooves 34 being such that the turns of the wire 32 protrude slightly therefrom, and hence rise above the exterior surface 35 of the forms 33. Both forms used in the coils 30 and 3| are identical, hence the description of coil 30 illustrated in Fig. 5 should suflice. The ends of the wire 32 are inserted through openings 36 formed in each end of each form 33 and bent under as shown at 31 on the interior of each form in order to hold the windings in place.
From the above description it should be obvious that the coils 30 and 3| are readily slidable within the tubes 20 and 2|, and that when the coils are engaged within said tubes 20 and 2|, the
outside diameter ofthe coils comprising the outi ermost surface of the windings will engage the inner surface of the tubes 20 and 2|, giving rise to a metal to metal contact.
The tubes 20 and 2| are provided with contacts at 38 and 39 adapted to be connected respectively to the wires of the transmission line H. Obviously the line I! should have animpedance matching that of the antenna.
I have thus far described the important portion of my invention and it will be seen that it consists of a di-pole antenna having distributed inductance therealong. The coils 30 and 3| provide inductance, and by arranging the coils so that their axes are aligned with those of the tubes 20 and 2| I have provided a physical antenna di-pole as well as inductance. The efficiency of such an antenna is greater than a short antenna having lumped inductive loading because the coils 30 and 3| are also in the electrostatic and electromagnetic fields of the video 6 waves and are enabled thereby to extract addi tional energy therefrom.
The antenna illustrated utilizes cylindrical tubes having a diameter of approximately two inches, whereby the antenna can receive broad band of frequencies without the discrimination against any portion of a channel. The effect accompanying such construction is a reduction of signal pick-up from the incident waves, but the coils 30 and 3| having added considerable inductance, the loss due to reduced Q is not as great as it otherwise would be.
Many advantages accrue as a result of the arrangement that I have described, irrespective of the construction including the turntable and adjustable stand-oil insulators. The necessity of using a large and unwieldy antenna is eliminated thereby enabling the entire antenna to be maintained within the room containing the receiving set. In the case of television receiving sets, my new antenna is so small that it can be mounted immediately upon the top of the cabinet of the television receiving set, thereby reducing transmission line length, cost, and losses. In addition to the above, since the antenna is immediately available to the observer, the same may be rotated so that it is properly oriented for maximum reception, that is, with the axis of the antenna dipole at right angles with a line from the transmitting station. In permanently mounted antennas, this cannot be done unless the installa tion is highly complicated, and consequently very expensive. With my new invention, the observer merely rotates the antenna turntable until optimum signal is obtained. Permanently mounted antennas must be oriented so that the direction in which they are arranged for reception is a resultant of directions of all the stations it is desired to receive. In such case, it is obvious that the signal to noise ratio for some stations may be prohibitive. Obviously, the great advantages of having a highly directive receiving antenna are lost if the antenna must be designed to remain fixed.
The advantage of ready orientation is achieved by reason of the antenna being so small as to readily be mountable in the immediate vicinity of the receiving equipment so as to be capable of manipulation by the observer. In addition to this, other great advantages accrue. Thus, per manently mounted antennas require tuning cir cuits in order to cause same efiiciently to receive all stations, since their physical size cannot readily be varied. On the other hand, my new antenna has means for tuning the antenna by varying the physical size as well as adjusting the distributed inductance thereof so that the optimum effective length of the antenna can immediately be achieved for any given station and condition of reception. The manner of accomplishing this will be explained hereinafter.
The coils 30 and 3| of my antenna are capable of being moved in and out of the tubes 20 and'2l by the observer. The turns of the coils that are enclosed within the tubes are short circuited since the wire 32 thereof is in engagement with the inner surface of the said tubes. This not only decreases the physical length of the di-pole antenna that cuts the video waves, but as well decreases the inductance of the coils 30 and 3|, and hence further decreases the effective length of the antenna. Obviously, not only is the antenna readily tunable, but it is readily tunable over an extremely wide range of frequencies so that it i its simple matter to tune the antenna to any station in the presently used television bands.
although manual movement of the coils is described herein, it should be obvious that any method of moving said coils, mechanically or electrically could be used, and in addition, the exact position of said coils for certain frequently received stations coul be calibrated thereon, or otherwise indicated. In addition the azimuth may be marked upon turntable II to properly orient the antenna.
It is Well known that the directivity of antennas can be improved by the use of parasitic antennas. 1 have consequently determined that the efficienc'y' of my new antenna is greatly increased by the use of a parasitic antenna serving as" a reflector to cause the antenna to be unidirectional. I have therefore mounted a parasit ic antenna 9 to the rear of di-pole i8, and have provided for adjustment of the distance between the antennas by means of the screws 25 and the slots 2t and 2?. The distance between antennas can thus be adjusted to one tenth the wave length of the received frequency, or whatever is optimum. This dimension is not critical, however, especially in the case of broad band reception where the thickness of the antenna proper is of the order of that dimension, and hence adjustment between the parasitic and dipole antennas may be eliminated, or the antenna may be adjusted for best reception over the entire band, and then fixed.
The parasitic antenna consists of a fixed central tube 59 mounted upon a standoff insulator 5i and having telescoping tubes 52 and 53 on the ends thereof. This provides for tuning of the parasitic antenna i9. This type of parasitic antenna acts as a reflector, serving to pick up additional energy from the passing video waves and reflect at proper phase into the dipole It.
It will be noted that the coils 3i) and 31 are not directly connected. to the transmission line [1. They are each produced as a unit and then telescoped into respective tubes 2c and 2!. enables shipping the antenna in a small container.
in Fig. 8 I have shown a modification of my invention which reverses the positions of the coils and tubes of the antenna heretofore described. The efiiciency of such antenna and the advantages are generally the same asv those of the antenna described. In the modified form of antenna the tubes 20 and 2! are formed as sleeves so and 6! which slide over the ends of the coils 62 and 83 respectively. The coils are both mounted upon a single form E l which is attached to the turntable H, and each has its inner terminus connected with the transmission line ii as shown at 65 and 6B. In all other respects the device is the same as described and is turnable in the same manner.
Although the parasitic antenna has been shown This constructed from tubing it should be obvious that same could also be formed of coils and tubes in the same manner as I form my di-poles. In addition, for high impedance transmission lines, various combinations of coils and tubes could be arranged in the form of a folded dipole to provide increased antenna impedance.
It is believed that this invention, its mode of construction and assembly, and many of its advantages should be readily understood from the foregoing Without further description, and it should also be manifest that while a preferred embodiment of the invention has been shown and described for illustrative purposes, the structural details are nevertheless capable of wide variation within the purview of this invention as defined in the appended claims.
What is claimed and desired to be secured by Letters Patent of the United States is:
1. A broad band television receiving antenna comprising horizontally arranged driven and parasitic elements spaced one in back of the other with their axes parallel and both perpendicular to the direction of the incident waves, the driven element comprising a pair of hollow metallic cylindrical tubes with a common axis, spaced one from the other along the axis and rigidly supported in such spaced position, a rotatable standard mounting said tubes, lead-in means electrically connected to said tubes to transmit the signal received when same are resonating as the halves of a dipole, each tube having a telescoping member in the outer end thereof, said member being formed of insulating material and having Wire helically arranged on the exterior thereof so that as the member is moved in and out of the respective tube, the tube will short circuit or uncover turns to tune the dipole, said parasitic element being a hollow cylindrical metal tube electrically continuous along its length secured to said standard and insulated therefrom.
2. A construction as described in claim 1 in which the parasitic element is formed of a central fixed cylindrical tube, and the ends thereof are formed as adjustably telescoped tubes in metallic contact therewith.
RUDOLPH RIDERMAN.
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Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2748387A (en) * 1953-12-23 1956-05-29 Hi Lo Tv Antenna Corp Antenna structure
US2755466A (en) * 1953-12-31 1956-07-17 Hi Lo Tv Antenna Corp Antenna structure
US2805414A (en) * 1955-05-26 1957-09-03 Itt Antenna structure
US2879507A (en) * 1956-04-25 1959-03-24 Shawnee Pottery Company Television antenna, light and tray
US2885673A (en) * 1957-04-16 1959-05-05 Bittner Louis Interchangeable ornamental indoor television antenna
US3052883A (en) * 1953-12-17 1962-09-04 Carroll J Rogers Adjustable dipole antenna
US3083364A (en) * 1958-07-23 1963-03-26 Andrew Corp Bifilar wound quarter-wave helical antenna having broadside radiation
US3623113A (en) * 1969-08-21 1971-11-23 Chu Associates Balanced tunable helical monopole antenna
US3961332A (en) * 1975-07-24 1976-06-01 Middlemark Marvin P Elongated television receiving antenna for indoor use
US3988737A (en) * 1975-10-02 1976-10-26 Middlemark Marvin P Pivoted rod television receiving antenna for indoor use
USD242863S (en) * 1975-06-26 1976-12-28 Middlemark Marvin P Four element indoor television antenna
US4101899A (en) * 1976-12-08 1978-07-18 The United States Of America As Represented By The Secretary Of The Army Compact low-profile electrically small vhf antenna
US4114161A (en) * 1963-06-21 1978-09-12 Sumitomo Electric Industries, Ltd. Magnetic current antenna
US4205318A (en) * 1979-01-15 1980-05-27 Pisano Vincent F Mini-indoor TV antenna
US6078298A (en) * 1998-10-26 2000-06-20 Terk Technologies Corporation Di-pole wide bandwidth antenna

Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1517570A (en) * 1921-02-17 1924-12-02 Joseph O Mauborgne System of radiocommunication
US1904208A (en) * 1930-11-14 1933-04-18 Jennings B Dow Variable inductance system
US2064585A (en) * 1935-05-07 1936-12-15 Mauricio P Atienza Radio antenna device
US2268664A (en) * 1934-09-29 1942-01-06 Rca Corp All-wave antenna system
US2311364A (en) * 1939-04-03 1943-02-16 Buschbeck Werner Broad-band antenna
US2471215A (en) * 1945-09-27 1949-05-24 Pye Ltd Radio antenna
US2474480A (en) * 1948-05-18 1949-06-28 American Phenclic Corp Antenna system
US2476469A (en) * 1945-04-30 1949-07-19 Joseph B Walker Adjustable antenna
US2495399A (en) * 1946-09-17 1950-01-24 Hazeltine Research Inc Antenna system

Patent Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1517570A (en) * 1921-02-17 1924-12-02 Joseph O Mauborgne System of radiocommunication
US1904208A (en) * 1930-11-14 1933-04-18 Jennings B Dow Variable inductance system
US2268664A (en) * 1934-09-29 1942-01-06 Rca Corp All-wave antenna system
US2064585A (en) * 1935-05-07 1936-12-15 Mauricio P Atienza Radio antenna device
US2311364A (en) * 1939-04-03 1943-02-16 Buschbeck Werner Broad-band antenna
US2476469A (en) * 1945-04-30 1949-07-19 Joseph B Walker Adjustable antenna
US2471215A (en) * 1945-09-27 1949-05-24 Pye Ltd Radio antenna
US2495399A (en) * 1946-09-17 1950-01-24 Hazeltine Research Inc Antenna system
US2474480A (en) * 1948-05-18 1949-06-28 American Phenclic Corp Antenna system

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3052883A (en) * 1953-12-17 1962-09-04 Carroll J Rogers Adjustable dipole antenna
US2748387A (en) * 1953-12-23 1956-05-29 Hi Lo Tv Antenna Corp Antenna structure
US2755466A (en) * 1953-12-31 1956-07-17 Hi Lo Tv Antenna Corp Antenna structure
US2805414A (en) * 1955-05-26 1957-09-03 Itt Antenna structure
US2879507A (en) * 1956-04-25 1959-03-24 Shawnee Pottery Company Television antenna, light and tray
US2885673A (en) * 1957-04-16 1959-05-05 Bittner Louis Interchangeable ornamental indoor television antenna
US3083364A (en) * 1958-07-23 1963-03-26 Andrew Corp Bifilar wound quarter-wave helical antenna having broadside radiation
US4114161A (en) * 1963-06-21 1978-09-12 Sumitomo Electric Industries, Ltd. Magnetic current antenna
US3623113A (en) * 1969-08-21 1971-11-23 Chu Associates Balanced tunable helical monopole antenna
USD242863S (en) * 1975-06-26 1976-12-28 Middlemark Marvin P Four element indoor television antenna
US3961332A (en) * 1975-07-24 1976-06-01 Middlemark Marvin P Elongated television receiving antenna for indoor use
US3988737A (en) * 1975-10-02 1976-10-26 Middlemark Marvin P Pivoted rod television receiving antenna for indoor use
US4101899A (en) * 1976-12-08 1978-07-18 The United States Of America As Represented By The Secretary Of The Army Compact low-profile electrically small vhf antenna
US4205318A (en) * 1979-01-15 1980-05-27 Pisano Vincent F Mini-indoor TV antenna
US6078298A (en) * 1998-10-26 2000-06-20 Terk Technologies Corporation Di-pole wide bandwidth antenna

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