SE522433C2 - Waveguide system comprising waveguides with different geometries, e.g. for mobile phones, has end of one waveguide insertible into other waveguide - Google Patents

Abstract

One of the waveguides (2) has an end section (7) which can be slid into the other waveguide (1) in order to form a connection (3) in between the two waveguides. An Independent claim is also included for a radio transmission unit comprising an antenna unit (4), a radio frequency unit (5) and the above waveguide system.

Description

20 25 30 35 -. u; u 522 433 hova- o u f f v s v | ~. | ø | o now 2 a mechanical connection, such as with a screw connection, bolt connection or clamping connection. However, the connection requires very high precision and low tolerances to achieve an adequate connection between the guides. This is both cumbersome and expensive, and the resulting connection of the waveguides is often far from perfect, leading to unacceptable losses and impaired polarization.

In order to avoid the above-related problems, it has been proposed to introduce an elastic or spring-mounted connection of one or both of the guide guides. As a result, lower tolerance requirements may be possible. However, even in this case, the precision becomes insufficient, which leads to a cumbersome and expensive assembly process, and a large amount of testing is required. Furthermore, the resilient connection of the guides is in itself expensive and cumbersome.

Object of the invention, and summary thereof It is therefore an object of the present invention to provide a waveguide system and a radio transmission unit, which reduce the above-related problems, and specifically allow less strict tolerance requirements.

This object is achieved with a waveguide system and a radio transmission unit in accordance with the appended claims.

According to the invention, there is provided a waveguide system comprising two tubular waveguides for electromagnetic waves and a connection interconnecting the waveguides, the waveguides having different geometries and said connection forming a transition between the waveguide of a first geometry and the waveguide of a second geometry. wherein the waveguide comprises a section slidably insertable into the second waveguide to form said connection.

Depending on the slidably insertable end section, a guide is provided which ensures a direct attachment. . n a u. 522 455 Ivan. v Q ~. u u ~ n - | I »n n o. 3 closure and a lateral alignment of the waveguides. Furthermore, the slidably insertable end portion provides a large tolerance range, within which a section may be allowed to be inserted with varying depths in the second waveguide. more reliable. Furthermore, the slidably insertable end section also allows subsequent variations during operation, such as length variations due to temperature differences, etc. This makes the waveguide system more reliable, and less exposed to loads and stresses, thereby increasing the service life of the system.

The geometries can either be circular geometries with different inner diameters, or both be substantially rectangular geometries with different cross-sectional areas. Preferably, however, the first geometry is a geometry with a secondary cross-section, and the second geometry is a geometry with a substantially rectangular cross-section. It is a geometry transition that is relatively common, especially in radio transmission units, and furthermore a geometry transition that has hitherto been particularly difficult to handle.

Furthermore, when the system is intended for polarized electromagnetic waves, the slidably insertable end section may comprise walls substantially only in the direction perpendicular to the polarization direction of the electromagnetic waves to be transmitted. Surprisingly, it has been shown by the applicant that the walls of the end section which are parallel to the direction of polarization can be eliminated without substantially affecting the behavior of the waveguide system. In this case, the walls of the guide wire in which the end section is inserted function as the walls of the connection. This increases the transverse dimension, ie the dimension perpendicular to the direction of polarization, of the connection. At the same time, less material is required, which makes the end section less expensive to manufacture. In cases where the end section is only partially inserted into the second waveguide, 10 15 20 25 30 35 n o v u: u arise. «U o nu .n n 522 433 I n o u v o I v Q o n | | | . r n I o n 4 more a slit-like gap in the connection. However, due to the fact that the gap is parallel to the polarization direction, the resulting losses become insignificant.

Preferably, the slidably insertable end section comprises an end-increasing cross-sectional area, forming at least one transition section with an intermediate geometry between the first and second geometries. Furthermore, the slidably insertable end section comprises at least a stepwise increase of the cross-sectional area. This results in a gradual transition between the different geometries.

According to another aspect of the invention, it further relates to a radio transmission unit comprising an antenna unit, a radio frequency unit and a waveguide system for transmitting electromagnetic waves between the antenna unit and the radio frequency unit, the waveguide system corresponding to the waveguide system discussed above.

Further features and applications of the present invention will become apparent from the detailed description given hereinafter. However, it is to be understood that the detailed description and the specific examples, which indicate preferred embodiments of the invention, are given by way of illustration only, as various changes and modifications within the scope and spirit of the invention will be apparent to those skilled in the art. those skilled in the art based on this detailed description.

Brief Description of the Drawings By way of example, the invention will be described in more detail in the following with reference to embodiments thereof illustrated in the accompanying drawings, in which: Fig. 1 is a longitudinal cross-sectional view of a waveguide interface between an antenna unit and a radio frequency unit in a radio transmission unit according to the prior art; 10 15 20 25 30 35 p f u »o q c, _ _ _. Sv. Ino. .en: nu .n-I n ... - n, p n 1. n u n o n; . Fig. 2 is a longitudinal cross-sectional view of a waveguide interface between an antenna unit and a. a radio frequency unit in a radio transmission unit according to a second prior art embodiment; Fig. 3 is a longitudinal cross-sectional view of a waveguide interface between an antenna unit and a radio frequency unit in a radio transmission unit in accordance with a preferred embodiment of the present invention; 4 is a cross-sectional view of the interface of FIG.

Description of Preferred Embodiments Referring to Fig. 3, in accordance with a preferred embodiment, a guide system comprises at least two tubular guides 1, 2 for electromagnetic waves and a connection 3 interconnecting the guides. The waveguides have different geometries, and the connection forms a transition between the waveguide of the first geometry and the waveguide of the second geometry. The geometries can both be circular geometries with different inner diameters, or both be substantially rectangular geometries with different cross-sectional areas. However, in the preferred embodiment, the geometry of the first waveguide 1 is a geometry with a circular inner cross-section, and the geometry of the second waveguide 2 is a geometry with a substantially rectangular inner cross-section.

The wall guides are preferably tubular and hollow and with reflective inner walls.

In the described embodiment, the waveguide system is part of a radio transmission unit, comprising an antenna unit 4, a radio frequency unit 5 and the waveguide system for transmission, ie transmitting and receiving electromagnetic waves between the antenna unit and the radio frequency unit. Such a radio transmission unit can, for example, be used in radio link systems between base stations for mobile communication, but also in other applications such as, for example, microwave systems. The antenna unit may be, for example, an antenna unit as described in US 4,963,878 and US 5,959,590, which documents are hereby incorporated by reference. A preferred frequency band for the operation of the radio transmission unit is between 7 and 40 GHz.

One of the waveguides comprises a section 7 which is slidably insertable in a telescopic manner in the second waveguide for forming said connection. In the preferred embodiment, where the guides have a circular or rectangular geometry, the guide 2 with the substantially rectangular geometry is provided with the end section 7. The end section preferably comprises parts projecting from a surface of the radio frequency unit 5 intended to the antenna unit 4.

For transmitting polarized electromagnetic waves, the slidably insertable end section 7, in accordance with a preferred embodiment, may comprise walls 7A substantially only in the direction perpendicular to the polarization direction of the electromagnetic waves to be transmitted. Consequently, walls 7B in the direction parallel to the polarization direction are removed, whereby the walls of the second wall conductor form the walls of the connection area. It is mainly the dimensions in the direction parallel to the polarization direction that determine the impedance of the waveguide. Consequently, by having substantially the same dimensions in the direction of polarization at the beginning of the end section as in the rectangular guide, a very low impedance can be obtained, which results in a very low degree of reflection. In the case where the end section is only partially inserted into the second guide, a slot-like gap 8 is formed in the connection. However, due to the fact that the gap is parallel to the polarization direction, the resulting losses are insignificant. The height of the gap is substantially the same as the height of the rectangular guide, and the width of the gap depends on the tolerance adjustment of the connection. It has been shown that the gap can have a maximum width in the range 0.5-1.0 of the height without any significant losses. 10 15 20 25 30 35 | ova nu 522 4th ~ I ~ ø cfuesn 7 Furthermore, it is preferred that the slidably insertable end section has at least over parts of its periphery an outer dimension which is substantially corresponding and slightly smaller than the inner dimension of that part of the duct. the waveguide into which the end section is intended to be inserted, and that the slidably insertable end section upon insertion into the second waveguide abuts against the inner surface of the second waveguide at least over parts of its periphery. Accordingly, in the case where the guide in which the end section is inserted has a circular geometry, it is preferable that the slidably insertable end section over at least a part of its outer surface has a circular geometry corresponding to the inner circular geometry of the other guide, and with a slightly smaller diameter.

Furthermore, it is preferred that the slidably insertable end section comprises an increasing cross-sectional area towards the end, forming at least one transition section with an intermediate geometry between the first and second geometries.

Variations in the cross-sectional area may be a continuous increase over certain distances in the longitudinal direction, but are preferably one or more stepwise increases (as illustrated in Fig. 3). The magnification is preferably in the direction of polarization of the electromagnetic waves to be transmitted in the waveguide, and the stepwise increase is preferably substantially a quarter of the wavelength of said electromagnetic waves.

With the waveguide system described above with the connection where one end section is inserted into the other waveguide in a telescopic manner, a highly adaptable and insensitive connection is achieved.

A preferred embodiment of the invention has now been described. However, it will be understood by those skilled in the art that many variations of the invention are possible. For example, the waveguide system according to the invention can be used for many other applications than in radio transmission units. Furthermore, the geometries can vary in other ways than being rectangular and circular. Vi- 522 45 :. In addition, the insertable part can be arranged on another of the guides, or even distributed with a part arranged on one guide and another on the other. The end portion may also comprise walls in all directions, or, as described above, only in certain directions. Such other similar variations must be considered as being within the scope of the invention as defined in the appended claims.

Claims (11)

10 15 20 25 30 35 S22 433: fä fi :: + æ @: fi :: r 9 PATENTKRAV A guide conductor system comprising two tubular guides for electromagnetic waves and a connection interconnecting the guides, the guides having different geometries and said connection forming a transition between the guide of a first geometry and the guide of a second geometry, the guides comprising an end section is slidably insertable in the second waveguide for forming said connection, characterized in that the waveguide system is arranged to transmit polarized electric waves, the slidably insertable end section comprising walls substantially only in the direction perpendicular to the polarization direction of the electromagnetic waves. the net waves to be transmitted. A waveguide system according to claim 1, wherein the first geometry is a geometry with a circular cross-section, and the second geometry is a geometry with a substantially rectangular cross-section. A waveguide system according to claim 1, wherein the first geometry is a circular geometry having a first inner diameter and the second geometry is a circular geometry having a second inner diameter, said second diameter being smaller than the first diameter. . A guide conductor system according to claim 1, wherein the first geometry is substantially rectangular geometry having a first cross-section and the second geometry is a substantially rectangular geometry having a second cross-section, said second cross-section having a smaller area than the first cross section. Guide guide system according to claim 2, wherein the guide guide of the substantially rectangular geometry comprises the end part which is slidably insertable into the guide guide of the circular geometry. A guide guide system according to any one of the preceding claims, wherein the slidably insertable end portion comprises an end-increasing cross-sectional area, forming at least one transition section with an intermediate geometry between the first and second geometries. Waveguide system according to claim 6, wherein the slidably insertable end section comprises at least a stepwise increase of the cross-sectional area. A waveguide system according to any one of the preceding claims, wherein the slidably insertable end portion of at least over a part of its periphery has an outer dimension which substantially corresponds to and is slightly smaller than the inner dimension of the part of the second waveguide in which the end section is intended to be inserted. A waveguide system according to claim 8 when dependent on claim 2, wherein the slidably insertable end portion over at least a portion of its outer surface has a circular geometry corresponding to the inner circular geometry of the second waveguide, and with a slightly smaller diameter . A waveguide system according to any one of the preceding claims, wherein the slidably insertable end portion when inserted into the second waveguide abuts at least over a portion of its periphery against the inner surface of the second waveguide. 11. ll. A radio transmission unit comprising an antenna unit, a radio frequency unit and a waveguide system for transmitting electromagnetic waves between the antenna unit and the radio frequency unit, the waveguide unit system comprising a waveguide of a first geometry fixedly connected to the antenna unit, a waveguide of a second geometry fixedly connected the radio frequency unit, said first geometry being different from said second geometry, and a connection between the waveguides, said connection forming a transition between the waveguides, one of the waveguides comprising an end portion which is slidably insertable into the second waveguide for forming said waveguide. connection, characterized in that the waveguide system is arranged to transmit polarized electric waves, the slidably insertable end section comprising walls substantially only in the direction perpendicular to the polarization direction of the electromagnetic waves to be transmitted.