US3246333A - Louvered radome - Google Patents

Louvered radome Download PDF

Info

Publication number
US3246333A
US3246333A US358523A US35852364A US3246333A US 3246333 A US3246333 A US 3246333A US 358523 A US358523 A US 358523A US 35852364 A US35852364 A US 35852364A US 3246333 A US3246333 A US 3246333A
Authority
US
United States
Prior art keywords
reflector
louvers
radome
aperture
antenna
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
US358523A
Inventor
Colin A Hacking
Alex S Bauer
Sammy N Watkins
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
GTE Sylvania Inc
Original Assignee
Sylvania Electric Products Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Sylvania Electric Products Inc filed Critical Sylvania Electric Products Inc
Priority to US358523A priority Critical patent/US3246333A/en
Application granted granted Critical
Publication of US3246333A publication Critical patent/US3246333A/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01QANTENNAS, i.e. RADIO AERIALS
    • H01Q1/00Details of, or arrangements associated with, antennas
    • H01Q1/42Housings not intimately mechanically associated with radiating elements, e.g. radome

Definitions

  • radio frequency intrusion detection apparatus The efiiciency of radio frequency intrusion detection apparatus is measured by its response to movement of particular objects, i.e., human intruders, in a protected area with a minimum of false alarms.
  • Rainstorms tend to increase the false alarm rates of such detection systems that protect areas located out-of-doors.
  • the false alarm rate during rainstorms has been controlled by decreasing the sensitivity of the system with a sacrifice of some detection capability. We have discovered a method of reducing the false alarm rate of the system without decreasing the system sensitivity.
  • An object of this invention is the provision, for vertically polarized antennas, of a radome capable of shedding rain and the like with minimum effect on the propagation of electromagnetic waves related to the antenna.
  • a specific object is the provision of a radome for the antenna of an outdoor radio frequency intrusion detection system which minimizes the false alarm rate of such system due to rain.
  • a plurality of louvers or slats of low loss dielectric material which is transparent to electromagnetic waves at the operation frequency are secured to the sides of the antenna radome made of like material.
  • the louvers are spaced apart at appropriate intervals to reduce the effective path length of rivulets of water flowing on the radome.
  • the louvers are positioned so that water rivulets running off the radome on the louvers are approximately orthogonal to the polarization of the antenna. The balance of run-off water is broken into droplets which have negligible effect on propagation even when the paths of fall of the droplets are parallel to the direction of polarization.
  • FIGURE 1 is a perspective view, partly cut away, of an antenna-radome assembly incorporating this invention
  • FIGURE 2 is a section of the assembly taken on line 22 in FIGURE 1;
  • FIGURE 3 is a transverse section taken on line 36 in FIGURE 2 showing a side view of the radome
  • FIGURE 4 is an enlarged section showing the radome louver construction and taken on line 4-4 in FIGURE 3;
  • FIGURE 5 is a modified form the assembly illustrated in FIGURE 2.
  • the antenna-radome assembly of FIGURE 1 comprises a corner reflector I which is illuminated by a collinear dipole array 2 that is protected from the elements by a radome 3.
  • Dipole array 2 preferably comprises a plurality of vertically plorazide dipoles 4 which extend in a vertical row for the height of the assembly.
  • Dipoles 4 are rigidly mounted on a channel 5 which houses the electrical feed circuits of the dipoles.
  • Collinear dipole arrays are described in Chapter 11 of Antennas by John D. Kraus, *McGraw-Hill Book Company, Inc., 1950.
  • Corner reflector v1 is similar to the type described in Chapter 11 of the Antenna Engineering Handbook by Henry Jasik, first edition, 1961, McGraw-Hill Book Company, Inc. As illustrated in FIGURES 1 and 2, the corner reflector comprises a conductive top plate 6, a conductive bottom plate 7, and a unit reflector plate 8 having a back 9 and forwardly divergent sides 10 and 11 with front edges defining the antenna aperture.
  • Conductive top plate 6 shields the radome 3 from rain and is slightly rearwardly inclined in order to drain collected water away from the antenna aperture.
  • the top plate 6 and bottom plate 7 are suitably rigidly mechanically and electrically connected to the reflector plate by bolts, not shown. Bottom plate 7 may also be inclined for drainage purposes.
  • Dipole array 2 is mounted in corner reflector 1 by vertically spaced flanges, one of which is shown at 12 in FIGURE 2, which are rigidly secured to channel 5 and to the back 9 of the reflector as by bolts.
  • the antennaradome assembly is elevated above bottom plate 7 by a pedestal P.
  • vertical mounting flanges 13 are rigidly secured to reflector plate sides 10 and 1.1, and horizontal mounting channels 14 are secured to reflector plate sides 10 and I l and back 9.
  • the junctions of channels 13 and 14 and the reflector plate are sealed, such as by potting, to prevent seepage of moisture through the junctions.
  • Radome 6 is secured in corner reflector 1 in channels 16 and 14 as described more fully hereinafter.
  • base plate 7 may be replaced by a narrow support member 15, shown in broken line in FIGURE 1, rigidly secured to reflector side plates 10 and ll and pedestal P.
  • Such an antenna-radome assembly preferably would be mounted in an elevated position on a vertical support column.
  • .Radome 3 comprises a shell -16 of mechanically strong low loss dielectric material through which electro-magnetic waves freely pass, such as a fiber glass laminate, to which are secured louvers or slats 17 made of the same material.
  • Shell 16 is a vertically extending trough-like enclosure comprising a central forward wall -18, side walls 19 and 20, and top and bottom walls 2 1 and 22 (see FIG- URES 2 and 3). Walls 21 and 22 seat tightly against side walls .19 and 20 and central wall 18 and are supported in the recesses of channels 13 and 14 on reflector plate 8.
  • the amount of energy coupled from a driven antenna to a parasite antenna is related to the cosine of the angle defined by the direction of polarization of the driven element and the longitudinal axis of the parasite antenna. No energy is induced in the parasite when it is orientated orthogonally to the polarization of the driven element. It has been determined that rivulets of water are efficient parasite antennas when they are parallel to the polarization of the antenna. In order to reduce amplitude modulation of a transmitted or received signal by these rivulets the direction of rivulet movement is made approximately orthogonal to the polarization of the driven antenna or dipoles 4.
  • the longitudinal axes of outwardly extending skirts 23 of adjacent louvers extend transversely of the direction of polarization. The skirts 23 are spaced apart slightly and inclined slightly, as indicated by the spacing a and angle a between the skirt longitudinal axis and the horizontal, respectively, in FIGURE 3.
  • the water is preferably directed toward the back 9 of reflector 8 where it drains from the
  • louvers 17 are inclined upwardly and outwardly from shell sides 19 and 20 so as to form a trough and catch water or if the louvers are oppositely inclined so as to shed water, as indicated in FIG- URE 4, the angle of inclination being designated 0.
  • the louvers are inclined upwardly or downwardly, they carry the greater part of the water off the radome even during heavy rainstorms.
  • the louvers are inclined downwardly, as shown in FIGURE 4, to shed water and to prevent undue accumulation of foreign material such as dirt or ice.
  • the water which falls from the long edges of the louvers is in droplet form that does not effect propagation of electromagnetic waves.
  • louvers 17a having enlarged skirts 23a of width e substantially larger than the skirt width a of the remaining skirts 23, are included in the row of louvers at appropriate vertically spaced intervals.
  • the substitution of one enlarged louver 17a for every tenth louver 17 as shown in FIGURE 1 gives satisfactory results.
  • Each enlarged louver shields the smaller louvers immediately below it and prevents excessive build-up of water on them.
  • radome 3 was formed of polyester pre-impregnated fiber glass reinforced laminate, shell 16 being formed in a mold and being comprised of several layers of the material. Shell end walls 21 and 22 and center wall 18 were reinforced with additional layers of the material. Louvers 17 and 17a were formed of several layers of this material in a heated press mold and were secured to the side walls 19 and 20 with resin adhesive.
  • Radome 3 is mechanically secured to the corner reflector .1 by connection of its center wall 18 to dipole circuit channel by bolts 24 (see FIGURE 2).
  • the side walls 19 and 20 seat against vertical mounting flanges 13 and the end walls 21 and 22 are supported in the recesses of horizontal mounting channels 14 and are sealed in place by a waterproof sealant.
  • FIGURE 5 A modified form of the invention is shown in FIGURE 5 in which the trough-like shell 16 of FIGURE 2 is replaced by a unit six-sided cup-like tubular shell 25 of laminated dielectric material, to the interior of which access is had only through an opening at the top.
  • Shell 25 may be filled with suitable insulator material such as polyurethane foam to prevent condensation within the shell.
  • the antenna-radome assembly of FIGURE 2 employing a radome having the following dimensions and characteristics, was constructed and successfully operated:
  • Radome louvers 16a Number 50. Incline, angle a 30 degrees. Slant/slope, angle 0 15 degrees. Spacing a 0.96 inch. Length 0 6.68 inches. Skirt width d 0.43 inch. Radome louvers 16a:
  • the effective gain fluctuations of this antenna-radome assembly were less than 0.1 db as compared with 0.5 db with a smooth surface radome.
  • An antenna-radome assembly comprising a corner reflector having vertically extending divergent sides with edges defining the reflector aperture
  • a vertically polarized dipole array for illuminating said reflector comprising a plurality of vertically aligned and spaced dipoles equally spaced from said reflector and located between the reflector and said aperture, and
  • a vertically extending electromagnetic wave transmitting radome enclosing said array comprising laterally spaced side Walls extending normally from the reflector sides, respectively, toward said aperture and a center wall connecting the side walls proximate to the aperture,
  • each of said side walls having a plurality of vertically spaced parallel louvers extending from the reflector to the center wall
  • each of said louvers being inclined downwardly toward the reflector and having a skirt projecting outwardly and down from the side wall
  • At least one of said louvers having a skirt which extends outwardly from the side wall a substantially greater distance than the skirts of said other louvers.
  • An antenna-radome assembly comprising a corner reflector having vertically extending divergent sides with edges defining the reflector aperture
  • a vertically polarized dipole array for illuminating said reflector comprising a plurality of vertically aligned and spaced dipoles equally spaced from said reflector and located between the reflector and said aperture, and
  • a vertically extending electromagnetic wave transmitting radome enclosing said array comprising laterally spaced side walls extending normally from the reflector sides, respectively, toward said aperture and a center wall connecting the side walls proximate to the aperture,
  • each of said side walls having a plurality of vertically spaced parallel louvers extending from the reflector to the center wall
  • each of said louvers being inclined downwardly toward the reflector and having a skirt projecting outwardly and down from the side wall.
  • An antenna-radome assembly comprising a corner reflector having sides forming an angle
  • a radome for protecting said dipole array comprising a shell of low loss dielectric material having shell sides extending from said corner reflector sides, respectively, and a center wall connecting said shell sides,
  • each of said first louvers having a skirt inclined to and extending from one of said shell sides to shed water and having a longitudinal axis approximately orthogonal to the vertical polarization of said dipole array, and
  • each of said second louvers having a skirt extending farther from said shell sides, than said first louvers skirt, and
  • a radome comprising a shell of low loss material
  • each of said louvers having a skirt extending outwardly from said shell
  • each of said skirts being inclined to the horizontal and having a longitudinal axis approximately orthogonal to the polarization of the operating means and inclined to the horizontal,
  • a radome comprising a shell of low loss material
  • each of said louvers having a skirt extending outwardly from said shell
  • each of said skirts being inclined to the horizontal and having a longitudinal axis approximately orthogonal to the polarization of the operating means and inclined to the horizontal.
  • a radome comprising a shell of low loss material
  • each of said louvers having a skirt extending outwardly from said shell
  • each of said skirts having a longitudinal axis approximately orthogonal to the polarization of the operating means.
  • a radome comprising a shell of loW loss dielectric material
  • each of said louvers having a skirt extending outwardly from said shell.

Landscapes

  • Aerials With Secondary Devices (AREA)
  • Details Of Aerials (AREA)

Description

A ril 12, 1966 Filed April 9, 1964 C. A- HACKING ETAL LOUVERED RADOME 2 Sheets-Sheet 1 3 INVENTORS COLIN A. HACKING ALEX s. BAUER SAMMY N. WATKINS ATTORNEY April 12, 1966 c. A. HACKING ETAL 3,246,333
LOUVERED RADOME Filed April 9, 1964 2 Sheets-Sheet 2 F I E- 3 4: no 1 l u j- I 1n I E 5 INVENTORS COLlN A. HACKING ALEX S. BAUER SAMMY N. WATKINS ATTORNEY United States Patent 3,246,333 LOUVERED RADOME Colin A. Hacking, Palo Alto, Alex S. Bauer, Sunnyvale, and Sammy N. Watkins, San Jose, Calif., assignors to Sylvania Electric Products Inc., a corporation of Delaware Filed Apr. 9, 1964, Ser. No. 358,523 7 Claims. (Cl. 343-872) This invention relates to intrusion detection systems and more particularly to an improved antenna radome for radio frequency detection systems that are exposed to the weather.
The efiiciency of radio frequency intrusion detection apparatus is measured by its response to movement of particular objects, i.e., human intruders, in a protected area with a minimum of false alarms. Rainstorms tend to increase the false alarm rates of such detection systems that protect areas located out-of-doors. In the past, the false alarm rate during rainstorms has been controlled by decreasing the sensitivity of the system with a sacrifice of some detection capability. We have discovered a method of reducing the false alarm rate of the system without decreasing the system sensitivity.
We have determined that raindrops falling on the exposed radome do not diffuse into a thin tfilm of water which runs evenly off the radome surface but rather merge together to form continuous vertical [filaments or rivulets which flow across the radome in an erratic pattern. The size and position of these rivulets continually change. We have discovered that these rivulets act as parasitic antennas; when parallel to the polarization of the driven antenna, they absorb maximum energy from the driven antenna and reradiate it. Since the amount and direction of this reradiated energy are continually changing, the effective gain of the antenna fluctuates. In other words, electromagnetic energy passing through the radome is essentially amplitude-modulated by water rivulets on the radome surface, and this causes the system to give false alarms.
An object of this invention is the provision, for vertically polarized antennas, of a radome capable of shedding rain and the like with minimum effect on the propagation of electromagnetic waves related to the antenna.
A specific object is the provision of a radome for the antenna of an outdoor radio frequency intrusion detection system which minimizes the false alarm rate of such system due to rain.
In accordance with this invention, a plurality of louvers or slats of low loss dielectric material which is transparent to electromagnetic waves at the operation frequency are secured to the sides of the antenna radome made of like material. The louvers are spaced apart at appropriate intervals to reduce the effective path length of rivulets of water flowing on the radome. The louvers are positioned so that water rivulets running off the radome on the louvers are approximately orthogonal to the polarization of the antenna. The balance of run-off water is broken into droplets which have negligible effect on propagation even when the paths of fall of the droplets are parallel to the direction of polarization.
This invention and these and other of its objects will be more fully understood from the following detailed deice scription of an illustrative embodiment thereof, reference being had to the accompanying drawings in which:
FIGURE 1 is a perspective view, partly cut away, of an antenna-radome assembly incorporating this invention;
FIGURE 2 is a section of the assembly taken on line 22 in FIGURE 1;
FIGURE 3 is a transverse section taken on line 36 in FIGURE 2 showing a side view of the radome;
FIGURE 4 is an enlarged section showing the radome louver construction and taken on line 4-4 in FIGURE 3; and
FIGURE 5 is a modified form the assembly illustrated in FIGURE 2.
The antenna-radome assembly of FIGURE 1 comprises a corner reflector I which is illuminated by a collinear dipole array 2 that is protected from the elements by a radome 3. Dipole array 2 preferably comprises a plurality of vertically plorazide dipoles 4 which extend in a vertical row for the height of the assembly. Dipoles 4 are rigidly mounted on a channel 5 which houses the electrical feed circuits of the dipoles. Collinear dipole arrays are described in Chapter 11 of Antennas by John D. Kraus, *McGraw-Hill Book Company, Inc., 1950.
Corner reflector v1 is similar to the type described in Chapter 11 of the Antenna Engineering Handbook by Henry Jasik, first edition, 1961, McGraw-Hill Book Company, Inc. As illustrated in FIGURES 1 and 2, the corner reflector comprises a conductive top plate 6, a conductive bottom plate 7, and a unit reflector plate 8 having a back 9 and forwardly divergent sides 10 and 11 with front edges defining the antenna aperture. Conductive top plate 6 shields the radome 3 from rain and is slightly rearwardly inclined in order to drain collected water away from the antenna aperture. The top plate 6 and bottom plate 7 are suitably rigidly mechanically and electrically connected to the reflector plate by bolts, not shown. Bottom plate 7 may also be inclined for drainage purposes.
Dipole array 2 is mounted in corner reflector 1 by vertically spaced flanges, one of which is shown at 12 in FIGURE 2, which are rigidly secured to channel 5 and to the back 9 of the reflector as by bolts. The antennaradome assembly is elevated above bottom plate 7 by a pedestal P.
As illustrated in FIGURE 2, vertical mounting flanges 13 are rigidly secured to reflector plate sides 10 and 1.1, and horizontal mounting channels 14 are secured to reflector plate sides 10 and I l and back 9. The junctions of channels 13 and 14 and the reflector plate are sealed, such as by potting, to prevent seepage of moisture through the junctions. Radome 6 is secured in corner reflector 1 in channels 16 and 14 as described more fully hereinafter.
It may be desirable, where the antenna-radome assembly is exposed to snow, to provide a corner reflector without a base wall so as to prevent undue accumulation of snow. For such applications, base plate 7 may be replaced by a narrow support member 15, shown in broken line in FIGURE 1, rigidly secured to reflector side plates 10 and ll and pedestal P. Such an antenna-radome assembly preferably would be mounted in an elevated position on a vertical support column.
.Radome 3 comprises a shell -16 of mechanically strong low loss dielectric material through which electro-magnetic waves freely pass, such as a fiber glass laminate, to which are secured louvers or slats 17 made of the same material. Shell 16 is a vertically extending trough-like enclosure comprising a central forward wall -18, side walls 19 and 20, and top and bottom walls 2 1 and 22 (see FIG- URES 2 and 3). Walls 21 and 22 seat tightly against side walls .19 and 20 and central wall 18 and are supported in the recesses of channels 13 and 14 on reflector plate 8.
The amount of energy coupled from a driven antenna to a parasite antenna is related to the cosine of the angle defined by the direction of polarization of the driven element and the longitudinal axis of the parasite antenna. No energy is induced in the parasite when it is orientated orthogonally to the polarization of the driven element. It has been determined that rivulets of water are efficient parasite antennas when they are parallel to the polarization of the antenna. In order to reduce amplitude modulation of a transmitted or received signal by these rivulets the direction of rivulet movement is made approximately orthogonal to the polarization of the driven antenna or dipoles 4. The longitudinal axes of outwardly extending skirts 23 of adjacent louvers extend transversely of the direction of polarization. The skirts 23 are spaced apart slightly and inclined slightly, as indicated by the spacing a and angle a between the skirt longitudinal axis and the horizontal, respectively, in FIGURE 3. The water is preferably directed toward the back 9 of reflector 8 where it drains from the assembly.
It has been determined empirically that the system operates satisfactorily if the louvers 17 are inclined upwardly and outwardly from shell sides 19 and 20 so as to form a trough and catch water or if the louvers are oppositely inclined so as to shed water, as indicated in FIG- URE 4, the angle of inclination being designated 0. Whether the louvers are inclined upwardly or downwardly, they carry the greater part of the water off the radome even during heavy rainstorms. In a preferred form of the invention, the louvers are inclined downwardly, as shown in FIGURE 4, to shed water and to prevent undue accumulation of foreign material such as dirt or ice. The water which falls from the long edges of the louvers is in droplet form that does not effect propagation of electromagnetic waves.
As droplets fall from the long edges of the upper louver skirts and merge with run-off water from lower louvers, there is a tendency for the accumulation of water to form into vertical rivulets which adversely affect antenna gain. In order to avert this occurrence, a few louvers 17a, having enlarged skirts 23a of width e substantially larger than the skirt width a of the remaining skirts 23, are included in the row of louvers at appropriate vertically spaced intervals. For example, the substitution of one enlarged louver 17a for every tenth louver 17 as shown in FIGURE 1 gives satisfactory results. Each enlarged louver shields the smaller louvers immediately below it and prevents excessive build-up of water on them.
In an actual embodiment of the invention, radome 3 was formed of polyester pre-impregnated fiber glass reinforced laminate, shell 16 being formed in a mold and being comprised of several layers of the material. Shell end walls 21 and 22 and center wall 18 were reinforced with additional layers of the material. Louvers 17 and 17a were formed of several layers of this material in a heated press mold and were secured to the side walls 19 and 20 with resin adhesive.
Radome 3 is mechanically secured to the corner reflector .1 by connection of its center wall 18 to dipole circuit channel by bolts 24 (see FIGURE 2). The side walls 19 and 20 seat against vertical mounting flanges 13 and the end walls 21 and 22 are supported in the recesses of horizontal mounting channels 14 and are sealed in place by a waterproof sealant.
A modified form of the invention is shown in FIGURE 5 in which the trough-like shell 16 of FIGURE 2 is replaced by a unit six-sided cup-like tubular shell 25 of laminated dielectric material, to the interior of which access is had only through an opening at the top. In other respects the antenna assemblies are the same. Shell 25 may be filled with suitable insulator material such as polyurethane foam to prevent condensation within the shell.
By way of example, the antenna-radome assembly of FIGURE 2, employing a radome having the following dimensions and characteristics, was constructed and successfully operated:
Antenna operating frequency 1.72. gc. Radome louvers 16:
Number 50. Incline, angle a 30 degrees. Slant/slope, angle 0 15 degrees. Spacing a 0.96 inch. Length 0 6.68 inches. Skirt width d 0.43 inch. Radome louvers 16a:
Number 4. Skirt width 2 1.3 inches.
The effective gain fluctuations of this antenna-radome assembly were less than 0.1 db as compared with 0.5 db with a smooth surface radome.
Although this invention has been illustrated and described in relation to a specific embodiment, it is understood that the scope of the invention is not limited thereto, but is determined by the scope of the appended claims.
What is claimed is:
1. An antenna-radome assembly comprising a corner reflector having vertically extending divergent sides with edges defining the reflector aperture,
a vertically polarized dipole array for illuminating said reflector comprising a plurality of vertically aligned and spaced dipoles equally spaced from said reflector and located between the reflector and said aperture, and
a vertically extending electromagnetic wave transmitting radome enclosing said array comprising laterally spaced side Walls extending normally from the reflector sides, respectively, toward said aperture and a center wall connecting the side walls proximate to the aperture,
each of said side walls having a plurality of vertically spaced parallel louvers extending from the reflector to the center wall,
each of said louvers being inclined downwardly toward the reflector and having a skirt projecting outwardly and down from the side wall,
at least one of said louvers having a skirt which extends outwardly from the side wall a substantially greater distance than the skirts of said other louvers.
2. An antenna-radome assembly comprising a corner reflector having vertically extending divergent sides with edges defining the reflector aperture,
a vertically polarized dipole array for illuminating said reflector comprising a plurality of vertically aligned and spaced dipoles equally spaced from said reflector and located between the reflector and said aperture, and
a vertically extending electromagnetic wave transmitting radome enclosing said array comprising laterally spaced side walls extending normally from the reflector sides, respectively, toward said aperture and a center wall connecting the side walls proximate to the aperture,
each of said side walls having a plurality of vertically spaced parallel louvers extending from the reflector to the center wall,
each of said louvers being inclined downwardly toward the reflector and having a skirt projecting outwardly and down from the side wall.
3. An antenna-radome assembly comprising a corner reflector having sides forming an angle,
a vertically polarized longitudinal dipole array for illuminating said corner reflector, said array being symmetrically located in said corner reflector,
a radome for protecting said dipole array, said radome comprising a shell of low loss dielectric material having shell sides extending from said corner reflector sides, respectively, and a center wall connecting said shell sides,
a pluarity of first louvers of low loss dielectric material secured to said shell sides, each of said first louvers having a skirt inclined to and extending from one of said shell sides to shed water and having a longitudinal axis approximately orthogonal to the vertical polarization of said dipole array, and
a plurality of second louvers of low loss dielectric material secured to said shell sides, each of said second louvers having a skirt extending farther from said shell sides, than said first louvers skirt, and
means for securing said radome and dipole array to said corner reflector.
4. In a system comprising means for operating on electromagnetic energy and a radome for protecting said operating means, a radome comprising a shell of low loss material, and
a plurality of low loss louvers secured to said shell,
each of said louvers having a skirt extending outwardly from said shell,
each of said skirts being inclined to the horizontal and having a longitudinal axis approximately orthogonal to the polarization of the operating means and inclined to the horizontal,
the skirt of certain of said louvers extending outwardly from said shell farther than said other louvers skirts.
5. In a system comprising means for operating on electromagnetic energy and a radome for protecting said operating means, a radome comprising a shell of low loss material, and
a plurality of low loss louvers secured to said shell,
each of said louvers having a skirt extending outwardly from said shell,
each of said skirts being inclined to the horizontal and having a longitudinal axis approximately orthogonal to the polarization of the operating means and inclined to the horizontal.
6. In a system comprising means for operating on electromagnetic energy and a radome for protecting said operating means, a radome comprising a shell of low loss material, and
a pluarlity of low loss louvers secured to said shell,
each of said louvers having a skirt extending outwardly from said shell,
each of said skirts having a longitudinal axis approximately orthogonal to the polarization of the operating means.
7. In a system for operating on electromagnetic energy, a radome comprising a shell of loW loss dielectric material, and
a plurality of louvers of low loss dielectric material secured to said shell,
each of said louvers having a skirt extending outwardly from said shell.
No references cited.
HERMAN KARL SAALBACH, Primary Examiner.

Claims (1)

1. AN ANTENNA-RADOME ASSEMBLY COMPRISING A CORNER REFLECTOR HAVING VERTICALLY EXTENDING DIVERGENT SIDES WITH EDGES DEFINING THE REFLECTOR APERTURE, A VERTICALLY POLARIZED DIPOLE ARRAY FOR ILLUMINATING SAID REFLECTOR COMPRISING A PLURALITY OF VERTICALLY ALIGNED AND SPACED DIPOLES EQUALLY SPACED FROM SAID REFLECTOR AND LOCATED BETWEEN THE REFLECTOR AND SAID APERTURE, AND A VERTICAL EXTENDING ELECTROMAGNETIC WAVE TRANSMITTING RADOME ENCLOSING SAID ARRAY COMPRISING LATERALLY SPACED SIDE WALLS EXTENDING NORMALLY FROM THE REFLECTOR SIDES, RESPECTIVELY, TOWARD SAID APERTURE AND A CENTER WALL CONNECTING THE SIDE WALLS PROXIMATE TO THE APERTURE, EACH OF SAID SIDE WALLS HAVING A PLURALITY OF VERTICALLY SPACED PARALLEL LOUVERS EXTENDING FROM THE REFLECTOR TO THE CENTER WALL, EACH OF SAID LOUVERS BEING INCLINED DOWNWARDLY TOWARD THE REFLECTOR AND HAVING A SKIRT PROJECTING OUTWARDLY AND DOWN FROM THE SIDE WALL, AT LEAST ONE OF SAID LOUVERS HAVING A SKIRT WHICH EXTENDS OUTWARDLY FROM THE SIDE WALL A SUBSTANTIALLY GREATER DISTANCE THAN THE SKIRTS OF SAID OTHER LOUVERS.
US358523A 1964-04-09 1964-04-09 Louvered radome Expired - Lifetime US3246333A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
US358523A US3246333A (en) 1964-04-09 1964-04-09 Louvered radome

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US358523A US3246333A (en) 1964-04-09 1964-04-09 Louvered radome

Publications (1)

Publication Number Publication Date
US3246333A true US3246333A (en) 1966-04-12

Family

ID=23410004

Family Applications (1)

Application Number Title Priority Date Filing Date
US358523A Expired - Lifetime US3246333A (en) 1964-04-09 1964-04-09 Louvered radome

Country Status (1)

Country Link
US (1) US3246333A (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3680147A (en) * 1970-08-30 1972-07-25 Robert W Redlich Colinear antenna apparatus
US20130082896A1 (en) * 2011-09-29 2013-04-04 Andrew Llc Folded Tab Retention Twin Wall Radome and Method of Manufacture
IT202100024038A1 (en) * 2021-09-20 2023-03-20 Crea Srl “Lamellar module for 5G technology”

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
None *

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3680147A (en) * 1970-08-30 1972-07-25 Robert W Redlich Colinear antenna apparatus
US20130082896A1 (en) * 2011-09-29 2013-04-04 Andrew Llc Folded Tab Retention Twin Wall Radome and Method of Manufacture
US8860626B2 (en) * 2011-09-29 2014-10-14 Andrew Llc Folded tab retention twin wall radome and method of manufacture
IT202100024038A1 (en) * 2021-09-20 2023-03-20 Crea Srl “Lamellar module for 5G technology”

Similar Documents

Publication Publication Date Title
US5872544A (en) Cellular antennas with improved front-to-back performance
CA1196408A (en) Surveillance system employing a dual function floor mat radiator
US4977406A (en) Planar antenna
US7583238B2 (en) Radome for endfire antenna arrays
EP0186455A2 (en) A dipole array
WO2013055272A1 (en) Short range radar system
US3225351A (en) Vertically polarized microstrip antenna for glide path system
US5103241A (en) High Q bandpass structure for the selective transmission and reflection of high frequency radio signals
US3955201A (en) Radar randome antenna with switchable R.F. transparency/reflectivity
US3246333A (en) Louvered radome
US3964069A (en) Constant beamwidth antenna
JPH08288738A (en) Patch antenna array
KR101041852B1 (en) Radome of antenna system and method of manufacturing same
CA2310690A1 (en) Double slot array antenna
US3757343A (en) Slot antenna array
US5596337A (en) Slot array antennas
US4117491A (en) Logarithmically periodic loop antenna array with spaced filters in the coupling network
US2691102A (en) High gain vhf antenna system
WO1995023441A9 (en) Slot array antennas
US3545001A (en) Antenna feed comprising dipole array with conductive ground plane
CN115863974A (en) Energy selective antenna and design method thereof
MX156403A (en) IMPROVEMENTS IN ELECTRONIC ARTICLE SURVEILLANCE SYSTEM
JPH09167917A (en) Device for antenna unit
US3490026A (en) Dipole antenna with u-shaped directors
US3501767A (en) Ultra-high frequency table top dipole mat antenna