RU2349995C2 - Receiving active aerial - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: active antenna contains slot coupled antenna component and the input of low-noise amplifier. It is ensured by slotted coupling holes of the same geometry and slot width to length ratio 0.1…0.2 respectively. These holes are formed within the plated layer of substrate interior and within earth board surface of low-noise amplifier. They are arranged specifically under the printed wire, while input circuit of the amplifier presents microstrip segment provided under the specified perpendicular coupling holes. It is supplied with diode assembly. The low-noise amplifier board is electroconductive fixed on the plated lower board surface thus ensuring the slotted hole within earth board plane of the low-noise amplifier under the slotted hole within the plated layer of substrate interior.

EFFECT: higher technological effectiveness and reliability of receiving active antenna.

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Description

The invention relates to antenna technology and can be used to receive, amplify and filter radio signals, in particular as an active receiving antenna in the equipment of users of space navigation systems (GPS, GLONASS / GPS).

Known active receiving antenna, made in the form of a module, which contains a polycarbonate housing, consisting of a protective cap and a bottom cover with fastening elements to the conductive screen, an amplifier with filters, an antenna element and a cable with a connector at the end, made in a single assembly, moreover, the amplifier with filters is closed by a metal screen, an antenna element with an amplifier is placed inside the modular case, the cable is brought out, and the place where the cable exits from the case is crimped mechanically. This design does not provide sufficient mechanical strength for the antenna. A sufficient gain is also not provided at angles close to the screen plane, which leads to the loss of signals from satellites located near the horizon. The antenna is also not tight enough due to leaks in the connection points (Motorola GPS Products-On core User's Guide Revision 5.008 / 30/02, Motorola website: http://www.motorola.com/ru/).

Also known is a receiving active antenna comprising a printed conductor with a ceramic substrate, a low-noise amplifier (LNA) with ceramic filters, a coaxial cable with a high-frequency connector at the end, a cover with fasteners to a conductive screen that does not have mounting holes in the bottom cover, and when mounting an active antenna to a non-magnetic screen, an additional steel adapter plate is used (GPS Antenna / Rev. 2.05 (8/18/97) Motorola's website: http://www.motorola.com/ru/). However, this antenna does not provide sufficient mechanical strength and reliability in operation, as well as the necessary expansion of the radiation pattern.

The closest in technical essence to the proposed receiving active antenna is a receiving active antenna containing a substrate in the form of a glass-shaped body with a metallized internal cavity with a ledge, on top of which there is a printed conductor of the antenna element coated with a protective radiolucent layer, a low-noise amplifier located on the internal metallized the surface of the substrate, and the output of the coaxial cable is laid through the side metallized hole of the substrate, closed metal ized lid inside with a magnet and a threaded sleeve which is fastened in the inner ledge of the cavity substrate (RF №2274934 patent publ. 20.04.2006 g). The input of the low-noise amplifier is electrically connected to the printed conductor of the antenna element using a jumper, and the output of the coaxial cable is sealed with a rubber pipe with internal and external protrusions. The antenna has a wide radiation pattern due to the combination of the functions of the body and ceramic substrate, increased mechanical strength, reliability and miniature. However, the connection of the printed conductor of the antenna element with the input of the LNA is made using a jumper. This requires making a thin hole in the ceramic case-substrate, which is non-technological and complicates the process of metallization of the case and poses a risk of violation of the sealing of the internal volume of the antenna housing in which the LNA is located during operation of the antenna.

The basis of the invention is the task of improving the manufacturability and reliability of the receiving active antenna.

This is achieved by the fact that in the metallized layer of the inner cavity of the substrate and in the earth surface of the low-noise amplifier board, slot-like communication holes are made of the same geometric shape with a ratio of width to slit length of 0.1 -: - 0.2, respectively, located selectively under the printed conductor, and the input the amplifier circuit is made in the form of a microstrip line segment, which is located under the indicated communication holes perpendicular to it, and is equipped with a diode assembly, the low-noise amplifier board being electrically conductive mounted on the metallized bottom surface of the substrate, providing a slot-like hole in the earth plane of the low-noise amplifier board under the slot-like hole in the metallized layer of the inner cavity of the substrate.

Figure 1 presents a General view of the inventive receiving active antenna.

Figure 2 presents a view along arrow "A".

Figure 3 presents a General view of the receiving active antenna in a sealed design.

The receiving active antenna (Fig. 1) consists of an antenna element including a printed conductor 1 and a dielectric substrate 2 with metallization of the lower surface 3, in which a slot-like shape 4a is made, a low-noise amplifier board 5 with a slot-shaped communication hole 4b in the ground surface of the board, restrictive diode assembly 6, filter 7, high-frequency cable 8 with high-frequency connector 9 at the end, rubber pipe 10, cover 11 with a metal plate 12, a magnet 13 and a threaded sleeve 14.

The dielectric substrate 2 of the antenna element is made in the form of a cup-shaped body with a screen metallized inner surface 3 with a step and a metallized hole in the side wall, on top of which there is a printed conductor 1 of arbitrary shape. In the metallized layer 3 there is a slot-shaped communication hole 4a, which is located completely below the printing conductor 1 and whose center is offset from the center of the printing conductor, and its minimum size (slit width) is 0.1 ... 0.2 of the maximum size (slit length) . The substrate of the antenna element can be made of both high-strength ceramic and a dielectric polymer substance. The second embodiment of the body-substrate is cheaper, but less durable. Outside, the antenna element is covered with a protective radiolucent layer 15.

The low-noise amplifier 5 is made on a circuit board in the ground surface of which there is a slot-shaped communication hole 4b (slit), the geometric shape of the communication hole 4b is completely identical to the shape of the communication hole 4a in the metallized layer 3 of the glass-like case, and the LNA input circuit is made in the form of a microstrip line , which passes under the aforementioned slots perpendicular to them, crosses them and ends with a restrictive diode assembly 6 (figure 2).

The low-noise amplifier board is fixed with an electrical contact on the metallized lower surface of the substrate (in the inner cavity of the glass-like enclosure-substrate) in such a way that the slit-like communication hole 4b in the ground plane of the LNA board is strictly under the slit-like hole 4a in the metallized layer 3 of the glass-like substrate-case 2 and nothing is separated from him. The area of the slot-like communication hole 4b in the ground plane of the LNA board should be slightly larger than the area of the slot-like hole 4a in the metallized layer 3 of the substrate to compensate for the technological variation in the installation of the LNA board on the lower metallized surface of the substrate. Therefore, the excess of the characteristic dimensions of the communication hole 4b over the corresponding sizes of the communication hole 4a should be determined by the tolerance on the accuracy of the LNA board installation in the antenna substrate.

The location of the slit-like hole of the connection 4a in the lower metallized layer 3 of the substrate 2 relative to the printed conductor 1 (and therefore the location of the slit of the connection 4b on the LNA board), the dimensions of the slit-like hole and the length of the length of the microstrip line extending beyond the width of the slot are calculated, including and for the case of receiving circular polarization signals of a given direction of rotation. In the latter case, the printed conductor 1 must have a configuration that provides radiation (reception) of the field of circular polarization, and the gap should be selectively relative to the geometric shape of the printed conductor.

In order to filter out-of-band interference, low-noise amplifier circuitry includes filters, ceramic or surface acoustic waves (SAW filters). The use of SAW filters is preferable when an increase in the suppression of out-of-band interference is required, since it can have a larger number of links at smaller sizes than a ceramic filter. However, such a SAW filter has large band losses with a relatively wide (several percent) operating frequency band and should be located after the first amplification stage of the low-noise amplifier from the minimizing noise figure of the amplifier. If the operating conditions of the antenna are such that it is necessary to limit the influence of out-of-band interference already on the first cascade of amplification of a low-noise amplifier, then it is necessary to use a ceramic filter located at the input of a low-noise amplifier, or use both filters, a ceramic and a SAW filter, placing the first at the input of a low-noise amplifier , and the second after the first gain stage.

High-frequency cable 8 is used to connect the output of a low-noise amplifier 5 with a receiving device. One end of the high-frequency cable is passed through the rubber pipe 10 and soldered to the output of the low-noise amplifier board, and the high-frequency connector 9 is soldered to the other end.

The rubber pipe 10 has special protrusions for fixing, is tightly inserted into the metallized hole of the substrate body and serves to seal the output of the high-frequency cable 8 from the metallized inner cavity of the substrate body.

The cover 11 is basically made by free pouring flush with the lower edge of the housing of the space formed by the metal plate 12, the ledges of the dielectric housing and the side surface of the ring magnet 13, mounted in the center of the metal plate 12, with a self-hardening polymer composition, thereby forming a sealed connection of the cover with a glassy body. To ensure reliable electrical contact of the metal plate 12 with the metallization 3 of the substrate and to prevent the polymer composition from flowing onto the LNA board during pouring, the metal plate 12 must be pre-soldered along the perimeter to the metallization of the ledge of the housing, or glued with conductive adhesive.

A threaded sleeve 14. is mounted inside the ring magnet 13 (attached to the conductive plate 12). The ring magnet 13 and the threaded sleeve 14 are used to fasten the receiving active antenna to the screen plane 16. Mounting with the threaded sleeve 14 is used if the conductive screen is made of non-magnetic metal , and using a magnet 13, if the conductive screen is made of magnetic metal.

When an electromagnetic wave is incident on an antenna element formed by a printed conductor 1 and a dielectric substrate 2 with metallization of the lower surface 3, high-frequency oscillations arise in it, generating high-frequency currents on the conductive surfaces of the antenna element. The communication gap 4a in the metallization 3 of the substrate 2 of the antenna element is located so that it intersects the currents in the metallization 3 of the substrate. Due to this, a transverse electric field arises in the slot 4a, which excites high-frequency currents in the microstrip line of the input circuit of the low-noise amplifier, which is then fed into the input stage of the low-noise amplifier through a communication hole 4b located strictly below the slot 4a in the ground plane of the LNA board. In the low-noise amplifier 5, the signal is amplified, filtered using the built-in filter 7, and fed to the high-frequency cable 8, which in turn is connected to the input of the receiving device. The restrictive diode assembly 6 at the input of the low-noise amplifier serves to protect it from failure (burnout) in the presence of an extraneous signal of high power (interference). In the absence of high power interference, the diode assembly 6 does not affect the operation of the LNA circuit, since possesses infinitely large resistance. The low-noise amplifier board 5 is located inside a closed volume formed by a metallized internal cavity of the substrate body 2 and a metallized cover 11, and is isolated from direct exposure to an incident electromagnetic wave.

The radiation pattern of the claimed antenna, as in the prototype, is expanded by raising the antenna element above the screen plane 16 by forming a dielectric substrate with a metallized lower surface in the form of an inverted cup, on top of which there is a printed conductor 1 of arbitrary shape, as well as due to the presence of a dielectric layer on the side of the glass.

Figure 3 presents a completely sealed version of the inventive antenna with the output signal down, from the side of the cover. In this case, the receiving active antenna does not have a side hole in the substrate 2, the rubber pipe 10 and magnet 13, and the sealed high-frequency connector 9 is hermetically mounted on the all-metal cover 11 and connected inside the antenna to the LNA board output using a short and thin cable 8. The cover it is also electrically conductively fixed (sealed) in the ledge of the housing and threaded bushings 14 (at least two) are installed in it for reliable screw fastening of the antenna to the screen plane 16, and a groove 17 is made along its perimeter, filled with self-hardening polymer composition to ensure protection of the attachment point of the cover 11 to the ledge of the substrate body 2. In this embodiment, the antenna output is connected to the input of the receiving device using an additional (separate) cable.

Claims (4)

1. The receiving active antenna containing the antenna element, made in the form of a printed conductor located on top of a glass-like dielectric substrate with a metallized internal cavity with a ledge, coated with a protective radiolucent layer on the outside, a low-noise amplifier made on a circuit board with filters located in the internal metallized cavity of the substrate , coaxial cable with a high-frequency connector at the end, a cover with fasteners fixed in the ledge of the substrate, characterized in that in In the metallized layer of the inner cavity of the substrate and in the earthen surface of the low-noise amplifier board, slit-shaped communication holes of the same geometric shape with a ratio of width to slit length of 0.1 ÷ 0.2, respectively, are located selectively under the printed conductor, and the input circuit of the amplifier is made in the form of a microstrip line located under the indicated communication holes perpendicular to it and equipped with a diode assembly, the low-noise amplifier board is electrically conductively mounted on a metal Anna lower surface of the substrate, providing a determination of slot-like openings in the ground plane beneath the low noise amplifier board slotted metallized layer in the inner cavity of the substrate. 2. The receiving active antenna according to claim 1, characterized in that the cable outlet through a metallized hole is equipped with a rubber pipe. 3. The receiving active antenna according to claim 1, characterized in that one of the filters of the low-noise amplifier is made on surface acoustic waves. 4. The receiving active antenna according to claim 1, characterized in that the high-frequency connector is hermetically mounted at the bottom of the antenna on the all-metal cover and connected inside the antenna to the output of the low-noise amplifier board with a short cable, and a groove is made along the perimeter of the cover, filled with a self-hardening polymer composition.

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