CZ302377B6 - Communication antenna intended for attaching to a human body - Google Patents

Abstract

The present invention relates to a communication antenna consisting of a dielectric strip (2) having a length (d1), width (s1) and thickness (h), which is made of a flexible and light material with low losses for high frequency waves. The dielectric strip (2) is provided from the lower side with a lower strip (3) of a thin electrically conducting fabric of the same length and width as the length (d1) and the width (s1) of the dielectric strip (2) and from the upper side said dielectric strip (2) is provided with an upper strip (1) of a thin conducting fabric with the length (d2) and width (s2).

Description

Communication antenna designed for mounting on the body

Technical field

The present invention relates to a communication antenna which is intended to be attached to an operator's body.

BACKGROUND ART

Wireless radio mobile communication devices are currently among the most widely used means of communication. Their main domain is mobile telephony systems operated by mobile operators. However, an important segment of mobile communications is also special wireless networks operated by security forces such as the military, police or fire brigade. Networks can be large nationwide (Paegas - Matra), or even local, created ad-hoc among members of the aforementioned churches operating in the locality. Most of these networks use operating frequencies f _{p of the} order of 10 ² MHz and transmitting powers of the mobile stations of the order of 10 ° W due to the favorable propagation of electromagnetic waves. These applications have to meet some other requirements, in particular the range guarantee, This means that the system must ensure at least approximately the same range and quality of the connection in all directions, and the mobile terminal must not interfere with or limit the movement and activity of the operating or intervening person in the actions.

Meeting all of these requirements can be difficult in some cases. In order to fulfill the condition that the terminal must not interfere with or restrict the movement and activity of the operating or intervening person in the actions, the mobile terminal is attached to the person's belt, with the handset and microphone attached to the helmet. The interventionist has both hands free and is not restricted by the means of communication. However, antennas operating in mobile terminals may be a problem. The terminals are usually equipped with simple built-in antennas which operate in the immediate vicinity of the human body in the manner of attachment described above. This behaves at the operating frequencies as a material with a very high relative permittivity c _r ~ 50 to 60 and with very high tan losses δ ~ 0.5 to 1.2. Such a material is capable of retuning a nearby antenna and absorbing much of the radiated or received power. This significantly reduces the functionality and efficiency of the antenna. In addition, the body reflects the generated electromagnetic wave away from each other and the radiation on the other hand is largely shielded. Direct exposure of the body to electromagnetic radiation can also be a significant problem.

Known antenna solutions for body or garment placement include, in particular, U.S. Pat. No. 6,377,216 Bl, "Integral antenna conformable in three dimensions" by Cheadle and Kems,

23.4.2022, which is a basic mode microstrip patch antenna formed from a conductive flexible material integrable into a garment. A spatially reduced variant of the patch antenna is described in EP 0 637 094 B, "Antenna for mobile communication" by Uwano and Takahashi, 1.2.1995. This antenna is made of metal plates, the reduction is achieved by using one or more slots placed in the top radiating plate.

The same antenna is described in a conference paper by Ogawa, K. et al., "A Vera Laughs Shoulder Pad Planar Antenna for Mobile Radio Application", IEEE APS Symposium 1997, Montreal, Canada, pp. 406-409, 1997, and a journal article by Ogawa, K. et al., A Shlouder-Mounted Planar Antenna for Mobile Radio Application, IEEE Trans. On Vehicle Technology, Vol. 49, no. 3, s. 1041-1043, 2000. Another type of patch-plate patch antenna in the ground plate for integration into wearable textile systems is described in Hertleer, C. et al., "Apaerture-Coupled Patch Antenna for Integration into Wearable Textile Systems" , IEEE Antennas and Wireless Propagation Letters, Vol. 6, s. 392-395, 2007.

Said solutions represent antennas suitable for placement on garments which operate in basic modes with an effective length approximately equal to the wavelength with a unidirectional radiating direction.

These characteristics are characteristic. The main antenna bundle is directed forwards or backwards when the antenna is positioned vertically on the garment at chest, waist or leg level, or is oriented upward when the antenna is placed horizontally on the garment in the shoulder area. The disadvantage of these solutions is that they do not provide the omnidirectional radiating characteristic or, at the same time, the antero-posterior and vertical characteristic, they do not allow reception from all directions or from several directions in the neighborhood, including the vertical direction, respectively. These deficiencies are eliminated by the antenna and its variants, which is the subject of this application.

SUMMARY OF THE INVENTION

For this application it is necessary to use antennas designed to suppress the negative effects of its proximity when attached to the body. This can be ensured by providing a continuous metallic surface between the radiating element of the antenna and the body. This metal surface may be implemented as a screen 15 destroying the baffle, or an antenna type in which the metal surface is directly part of the antenna structure may be selected. The proposed solution uses the second possibility, the metal surface between the body and the shining element is directly part of the antenna. The communication antenna consists of a dielectric strip of length d1, width s1 and thickness h, which is a flexible and lightweight material with low losses for radio frequency waves. The dielectric strip is provided on the underside with a lower strip of thin conductive weave of a length and width equal to the length and width of the dielectric strip. From the upper side, the dielectric strip is provided with an upper strip of thin conductive fabric of length d2 and width s2, where d2 <dl and s2 <sl. At the same time, it must be fulfilled that the thickness h of the dielectric strip is typically in the range of 0.01 to 0.03 of the length d2 of the upper strip of thin conductive fabric. The antenna is provided with a coaxial cable for connection to a mobile communication means via a connector. The center conductor of the coaxial cable 25 is conductively connected to the antenna to the upper strip at a distance d3 from the edge of the upper strip of thin conductive fabric. The outer conductor of the coaxial cable is also conductively connected at a distance d3 to the lower conductive fabric web. The distance d3 lies in the range 0.1 to 0.2 of the length d2 and the entire antenna structure is provided with a thin protective dielectric film. The essence of the novel solution is that the dielectric strip provided with the lower and upper strips of thin conductive fabric is bent to be attached to the shoulder of the wearer so that the shoulder rests against the lower belt and the lengths of the sections extending forward and back over the shoulder are approximately equally long.

In one possible embodiment, the omni-directional antenna in the horizontal plane operates as a full wave antenna in the second resonant mode and has a dimension d2 equal to one wavelength corresponding to the operating frequency.

The advantage of the designed antenna is that it radiates forward and backward, with slight attenuation even to the sides. In one of these variants it also radiates upwards. Its performance is not radiated to the body, the body is not unnecessarily burdened with electromagnetic radiation. Another advantage is that the antenna parameters are only

4o very little influenced by the human body, radiation efficiency is not reduced. In addition, this communication antenna is light and flexible and can be part of a simple strap, vest or T-shirt, so it does not restrict the movement of a person.

BRIEF DESCRIPTION OF THE DRAWINGS

An example of a communication antenna to be attached to a body is shown in the attached drawings. Fig. 1 schematically shows the antenna before bending over the shoulder in a top view, where the top band of conductive fabric is located, Fig. 2 is a side view of the individual layers of the communication antenna, and Fig. 3 shows the application of the communication antenna and its connection to mobile terminal.

- 2 GB 302377 B6

DETAILED DESCRIPTION OF THE INVENTION

The structure of the communication antenna is shown in FIG. 1 and 2 with the proviso that when used on the body, the antenna is bent and secured over the shoulder of the person of FIG. 3. The base of the antenna is a dielectric strip 2 with a length d1, a width s_L and a thickness h. This dielectric strip 2 is made of a soft, flexible, lightweight and low-loss material in high frequency terms. Typically, plastic foam strips may be used. From the bottom of the dielectric strip 2, a bottom strip 3 made of a thin conductive fabric, the length and width of which correspond to the dimensions of the dielectric strip 2, is glued over the entire surface. A top conductive fabric web 1 of length d2 and width s2 is glued on top 10, with the dielectric web 2 along with the base web 3 on all sides overlapping the top web I to form a hem around the upper strip 1 of a thin conductive fabric. The thickness h of the dielectric strip 2 is in the range of 0.01 to 0.03 of the length d2 of the topsheet 1 of a thin conductive fabric. For working on the body, the communication antenna is protected by a thin dielectric foil that closes it tightly and protects it against the ingress of moisture. The entire antenna assembly thus formed is bent so that the antenna can be laid and attached to a person's arm. The bending is done so that the back and forth of the arm extend over approximately equal lengths. For example, the attachment to the arm may be such that the antenna is part of a strap that extends over the arm and is attached to the belt on both sides. The antenna can also be sewn in a garment such as a jacket, vest or t-shirt.

The application of the communication antenna is shown in FIG. 3.

The antenna is connected to the mobile terminal 5 by means of a thin coaxial cable 4. On the side of the mobile terminal 5, the coaxial cable 4 is provided with such a connector that can be connected to the antenna input / output of the used type of mobile terminal 5. is attached to the edge of the top sheet of thin conductive fabric at a distance d3 from the edge of the top sheet of thin conductive fabric. The outer conductor of the coaxial cable 4 is conductively connected to the lower strip 3 of thin conductive fabric, also at a distance d3, through an opening or recess in the dielectric strip. The distance d3 lies in the range of 0.1 to

0.2 of the length d2 of the upper belt 11.

In order to ensure the omnidirectional characteristic and / or the pre-rear directional characteristic in the horizontal plane, it is essential that the antenna is bent over the shoulder with the length dimension d2 and simultaneously the second resonance mode is excited. . Giant. 3 shows a second resonant mode antenna with a length d2 corresponding to one wavelength per operating frequency and with an omnidirectional characteristic in the horizontal plane. These modifications to the antenna geometry make it possible to establish connections in more directions than the prior art antennas,

Industrial applicability

The type of antenna can be advantageously used as an external antenna for mobile communication means for the needs of the army, police, fire brigade or wherever it is necessary to have free hands in communication while guaranteeing at least approximately the same range in all directions.

Claims (2)

5 1. The communication antenna intended to be attached to the body consists of a strip (2) of dielectrics of length (dl), width (sl) and thickness (h), which is a flexible and lightweight material with low losses for radio frequency waves. (2) the dielectric is provided with a lower band on the underside (3) of a thin conductive fabric with a length and width equal to the length (dl) and width (sl) of the band (2) a strip (1) of a thin conductive fabric as well as a length (d2) and a width (s2), where d2 <d 1 and s2 <s 1, the thickness (h) of the dielectric strip (2) being in the range 0.01 to 0.03 (d2), and the antenna is provided with a coaxial cable (4) for connection to the mobile communication means (5) via a connector, wherein the center conductor of the coaxial cable (4) is conductively connected to the antenna to the upper belt (1) at a distance (d3) from the edge of the upper strip (1) of a thin conductive fabric and the outer koa conductor of the xial cable (4) is also connected at a distance (d3) to the lower strip (3) of the thin conductive fabric, the distance (d3) being in the range of 0.1 to 0.2 of length (d2) and the entire antenna structure is provided with a thin protective dielectric film, characterized in that the dielectric strip (2) provided with a lower strip (3) and an upper strip (1) of a thin conductive fabric is bent for fastening to the user's arm such that it is supported by the lower strip (3) of thin conductive fabric and the length of the sections extending forwards and backwards 20 over the shoulder are approximately the same length. Communication antenna according to claim 1, characterized in that the length (d2) of the upper strip (1) of the thin conductive fabric has a dimension equal to one wavelength corresponding to the operating frequency.