RU154867U1 - PASSIVE RADIO AMPLIFIER - Google Patents

Abstract

1. A passive radio signal amplifier, which is a closed lattice of conductive material, made in the form of a two-dimensional self-similar structure (two-dimensional fractal), the planar dimensions of which are comparable to the planar dimensions of the active antenna of a communication device deposited on a dielectric base, said lattice being designed to be parallel to the active plane antennas of the communication device at the minimum possible distance from it so that the center of the said grating crosses electromagnetic radiation of the active antenna of the communication device, while the said passive amplifier of the radio signal does not contain a feeder and is connected to the antenna of the communication device only through the magnetic field of the antenna of the communication device. 2. The amplifier according to claim 1, characterized in that the said two-dimensional self-similar structure is a Sierpinski carpet fractal. 3. The amplifier according to any one of paragraphs. 1 or 2, characterized in that the planar dimensions of said conductive material grating are equal to or greater than the planar dimensions of said active antenna of the communication device. 4. The amplifier according to claim 3, characterized in that the planar dimensions of said grating are 16 × 16 mm or 32 × 32 mm. The amplifier according to any one of paragraphs. 1, 2 or 4, characterized in that the said dielectric base contains an adhesive base. The amplifier according to claim 3, characterized in that said dielectric base contains an adhesive base.

Description

FIELD OF TECHNOLOGY

The claimed utility model relates to devices for amplifying a radio signal, and more particularly, to passive amplifiers of a radio signal having a fractal structure of an amplifier array.

BACKGROUND

Various active antennas having a fractal lattice structure are known in the art (see, for example, US 7019695 B2 (COHEN NATHAN), 03/28/2006 (D1)). These antennas necessarily contain a feeder or other transmission line, which significantly reduces the area and usability of such active antennas.

The closest analogue (prototype) of the claimed solution is a passive radio signal amplifier (passive radio signal repeater) described in patent document JPH10209732 A (SANWA INSATSU KK), 08/07/1998 (D2). The passive radio signal amplifier known from D2 is a radio signal repeater comprising a plurality of closed parts made of various metals, the electrodes of which are connected to a flat base on one side of the receiving section to form a metal circuit in which pairs of electrodes are parallel to each other. The passive radio signal amplifier known from D2 is intended for installation on the housing of a mobile communication device or on the glass (window) plane of a room or vehicle.

The passive radio signal amplifier known from D2 does not have a fractal structure of the amplifier lattice, which significantly reduces the radio signal amplification efficiency.

DISCLOSURE OF A USEFUL MODEL

The advantages of the fractal structure of the antenna array are known from a number of publications, in particular, from publications [1-7]. Using the advantages of the fractal structure of the receiving array in the technical solution related to passive radio signal amplifiers (passive radio signal repeaters) allows one to achieve a significant increase in the radio signal amplification efficiency, which directly affects the quality of communication in general.

Thus, the objective of the claimed utility model is the creation of an effective passive (non-volatile) radio signal amplifier (radio signal repeater).

The technical result is to ensure the efficiency of amplification of the radio signal and improve the quality of communication of the communication device, which contains a passive amplifier of the radio signal according to this utility model, without increasing power consumption. Another technical result is the provision of an effective non-volatile passive amplifier of the radio signal. Another technical result is the improvement of the transceiver properties of the active antenna of a communication device without changing its circuitry.

The claimed technical result is achieved due to the fact that the passive amplifier of the radio signal is a closed lattice of conductive material made in the form of a two-dimensional self-similar structure (two-dimensional fractal), preferably a Sierpinski carpet fractal, the plane dimensions of which are equal to or exceed the plane dimensions of the active antenna of the device communication deposited on a dielectric base, wherein said grating is designed to be arranged parallel to the plane of the active antenna of the device a connection at the minimum possible distance from it so that the center of said grating line crossing active antenna communication apparatus of the electromagnetic radiation, said passive power radio signal does not contain the feeder and is connected to the antenna of the communication device only through the magnetic field of the antenna of the communication device. In some embodiments of the claimed utility model, the planar dimensions of said lattice are 16 × 16 mm or 32 × 32 mm. In some other embodiments of the claimed utility model, said passive amplifier comprises a fastener for mounting it on or in the housing of the communication device. The fastening element, respectively, can be, in particular, an adhesive base or a laminate film.

IMPLEMENTATION OF A USEFUL MODEL

The claimed passive amplifier of the radio signal is a closed lattice of conductive material made in the form of a two-dimensional self-similar structure (two-dimensional fractal), preferably a Sierpinski carpet fractal, the plane dimensions of which are equal to or greater than the plane dimensions of the active antenna of the communication device deposited on a dielectric base, wherein the grating is designed to be placed parallel to the plane of the active antenna of the communication device at the minimum possible distance from it so that the center of the said grating crosses the electromagnetic radiation line of the active antenna of the communication device, while the said passive radio signal amplifier does not contain a feeder and is connected to the antenna of the communication device only through the magnetic field of the antenna of the communication device. The fact that the passive amplifier does not have a feeder or any other power supply, but is connected to the antenna of the communication device only through the magnetic field of the antenna of the communication device, indicates that the claimed passive amplifier is non-volatile, and its radio-amplifying properties are manifested on the basis of the well-known principle of mutual induction. In some embodiments of the claimed utility model, the planar dimensions of said lattice are 16 × 16 mm or 32 × 32 mm. In some other embodiments of the claimed utility model, said passive amplifier comprises a fastener for mounting it on or in the housing of the communication device. The fastening element, respectively, can be, in particular, an adhesive base or a laminate film.

Planar dimensions are the length and width of the grating of a passive radio signal amplifier. Preferably, the length and width of the grating of a passive radio signal amplifier are equal to the length and width of its dielectric base on which said fractal grating is made. As the communication device, any known communication device containing an active flat (strip) antenna, such as a smartphone, cell phone, tablet computer, phablet, personal computer, external communication module (Wi-Fi or Bluetooth), etc. can be used. The conductive material may be any material known in the art having conductive properties, for example, a metal foil, in particular a gold foil.

The declared passive amplifier of the radio signal is parallel to the active antenna of the communication device at the minimum possible distance from it, determined by the design features of the passive amplifier of the radio signal and the active antenna of the communication device, while the center of the array of the passive amplifier of the radio signal crosses the electromagnetic radiation line of the active antenna of the communication device. The electromagnetic radiation generated by the active antenna of the communication device is projected onto the array of a passive radio signal amplifier. The resonance arising according to the principle of mutual induction increases the level of outgoing radiation of the active antenna of the communication device. In turn, by means of the aforementioned grating, external electromagnetic radiation is polarized and focused on the active antenna, which increases the sensitivity of the antenna of the communication device as a whole. Thus, the passive amplifier used in the claimed communication device is non-volatile. The efficiency coefficient of the application of the claimed passive amplifier of the radio signal in both cases is determined by the geometric dimensions of both elements (active antenna of the communication device and the array of the passive amplifier of the radio signal) and the order of the fractal pattern of the amplifier.

The lattice of the passive amplifier of the radio signal located above the emitting plane of the active antenna is made in the form of a cascade of self-similar structures from the model of bending of the conductive material by an angle, preferably determined by the Sierpinski carpet fractal or any other fractal, if the planar dimensions of the passive amplifier and the active are comparable antennas of a communication device. The full matrix of A-parameters of the entire lattice can be determined as the degree of the transfer matrices [a] for the elementary structure and reduced to the form:

The input impedance, respectively, is determined by the ratio:

where All, A12, A21 are the elements of the matrix of the equivalent closed loop, which are determined by expression (1).

So, for a radio signal amplifier based on the first-order Sierpinski carpet fractal with plane dimensions of 32 × 32 mm, located above the conductive plane of the active antenna of a communication device of comparable size and made of conductive material 100 μm thick, at a height above the screen of the active antenna h = 1 mm, coefficients of 1.273-1.826 were obtained with mutual induction at resonance frequencies of 0.093-6.517 GHz.

A passive radio signal amplifier is made by giving the conductive material a self-similar geometric shape, in particular, the shape of the Sierpinski carpet fractal. However, any geometric shape can be used. The choice of the geometric shape is determined only by the need for the planar dimensions of the fractal lattice of the passive amplifier to be comparable or, at a minimum, exceed the planar dimensions of the antenna of the radio communication device. Such a structure can be obtained by known methods, in particular, additive and subtractive.

In particular, in the case of the additive method, from the base, which is an insulating material (dielectric), in particular textolite or fiberglass, thick paper, polymer material, the required basic geometric two-dimensional shape of the passive repeater is cut. The thickness of the dielectric is determined by the required mechanical and / or electrical strength. The base in this case, respectively, may also contain an adhesive base for attaching it to an element of the communication device. Then, a conductor in the form of a foil material (metal foil) is applied to the obtained two-dimensional main form. The choice of foil material is carried out on the basis of the requirements for material consumption of the manufacturing process of the claimed passive repeater, as well as the required gain. The foil material is applied to the obtained main two-dimensional form by means of the hot stamping method using a mold that most accurately repeats the fractal pattern of the passive repeater.

In the case of the subtractive method, the required basic two-dimensional form of the passive repeater is first made of an insulating material containing a metallized coating on one side. After that, the pattern of the fractal lattice of the passive repeater is applied to the obtained form with a protective layer and etched unprotected areas are chemically used, for example, by etching in an aqueous solution of iron chloride. The protective layer, in particular, can be applied by photolithographic method.

At the same time, it should be obvious to a person skilled in the art that other methods of applying foil material to a dielectric in such a way that a fractal array of a passive radio signal amplifier is created by foil material can be used if such methods provide the required accuracy and order of the fractal lattice. Such methods, in particular, may be a laser engraving method, as well as some high-precision machining methods.

The present description of the implementation of the claimed utility model demonstrates only a particular embodiment and does not limit other embodiments of the claimed utility model, in particular, other forms of the fractal structure of the lattice of a passive amplifier, since possible alternative embodiments of the claimed utility model do not go beyond the scope of the information set forth in of this application should be obvious to a person skilled in the art having the usual qualifications for which declared utility model.

List of non-patent sources cited:

1. Flexible Substrate Antennas (HINDAWI PUBLISHING CORPORATION), 2012.

2. Study of the "Sierpinski's Carpet" Fractal Planar Antenna by the Renormalization Method (C. LARBI et al.), 01/01/2007.

3. Stacked Microstrip Patch Antenna: Gain and Bandwidth Improvement, Effect of patch rotation A (RUSHIT D TRIVEDI et al.), 12/31/2014.

4. Experimental Study of Stacked Rectangular Microstrip Antenna for Dual-Band (RAJESH KUMAR VISHWAKARMA et al.), 02.2010.

5. A STACKED MICROSTRIP PATCH ANTENNA WITH FRACTAL SHAPED DEFECTS (H. TIWARI et al), 2010.

6. STACKED SIERPINSKI CARPET FRACTAL ANTENNA FOR X-BAND APPLICATIONS (ANUJ ATTRI), 07.2013.

7. Fractal antennas (V.I. SLYUSAR), 09.2002.

Claims (6)

1. A passive radio signal amplifier, which is a closed lattice of conductive material, made in the form of a two-dimensional self-similar structure (two-dimensional fractal), the planar dimensions of which are comparable to the planar dimensions of the active antenna of a communication device deposited on a dielectric base, said lattice being designed to be parallel to the active plane antennas of the communication device at the minimum possible distance from it so that the center of the said grating crosses the line electromagnetic radiation of the active antenna of the communication device, wherein said passive amplifier of the radio signal does not contain a feeder and is connected to the antenna of the communication device only through the magnetic field of the antenna of the communication device. 2. The amplifier according to claim 1, characterized in that the said two-dimensional self-similar structure is a Sierpinski carpet fractal. 3. The amplifier according to any one of paragraphs. 1 or 2, characterized in that the planar dimensions of said lattice of conductive material are equal to or greater than the planar dimensions of said active antenna of a communication device. 4. The amplifier according to claim 3, characterized in that the planar dimensions of said lattice are 16 × 16 mm or 32 × 32 mm. 5. The amplifier according to any one of paragraphs. 1, 2 or 4, characterized in that the said dielectric base contains an adhesive base. 6. The amplifier according to claim 3, characterized in that the said dielectric base contains an adhesive base.