BRPI0608588A2 - phasor for continuous phase adjustment - Google Patents

Abstract

PHASE FOR CONTINUOUS PHASE ADJUSTMENT. The present invention relates to phasers for continuous phase adjustment and specifically to a phaser for use in base station antennas for adjusting beam tilt. The phaser includes a metal chamber and a pair of fixed transmission lines and a mobile transmission line placed in the metal chamber. The mobile transmission line is configured in "U" format. Each of the fixed transmission lines defines a longitudinal channel at one end thereof. Two arms of the mobile transmission line are received in the fixed transmission line channels. A cross section of each arm of the mobile transmission line is configured as a rectangle shape. The cross section of the fixed transmission lines in which the channel is defined is configured as a rectangular frame provided with staves with one side of it being omitted. Integratively designed fixed drive lines are readily fabricated through a mechanical process or side mold release from a mold process. After the cross section of the transmission lines has been changed from a circular to a rectangular shape, the phaser volume can be reduced by providing transmission line staves. In addition, the phaser of the present invention may also inhibit passive intermodulation and high disruptive discharge products.

Description

PHASE CONTINUOUS ADJUSTMENT PHASE

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to 5 phase shifters for continuous phase adjustment and, more specifically, to a shifter used to adjust the beam tilt of a base station antenna.

2. Description of Related Technique

To optimize worked cell 10 wireless signal coverage and suppress wireless interference (ie co-frequency interference) from other co-frequency cells, mobile base station antennas are required to adjust suitably beam directions in vertical patterns to tilt their directional angles downward with respect to horizontal directions (i.e. downward beam inclination). In many complex uses of base station antennas, signal coverage and co-frequency interference are often constantly changing and therefore the angles of

Downward beam tilt (ie beam scan) are also continuously variable with time and angle locations. These types of base station antennas are commonly referred to as continuously adjustable beam downward tilt base station antennas.

Offsetters are important components of continuously adjustable beam downward tilt base station antennas. In general, a beam forming network for adjustment

Phase Continuous Phase 0608588-1 includes several phase shifters to achieve the electrical downward tilt of the base station antennas, the theory of which comes from the well-known beam scan theory of in-phase radar antenna array. However, phased array antenna phasers used in beam forming networks are usually quantified digital phasers with high manufacturing cost. In addition, quantized digital phasers are able to form direction deviations from beam descending inclination angles and are unlikely to continuously vary beam descending inclination angles.

In order to satisfy the functions of electric downward tilt base station antennas, inexpensive phasors for continuous phase adjustment are of great importance. In conventional technology, phase shifters for continuous phase adjustment are described in U.S. Patent No. 2,502,359 issued in 1950.

Referring to Figure 1, a metal chamber 390 includes two bilateral symmetrical bodies 3 90A, 390B held together by pins 391. Signals transmitted into the metal chamber 390 via a coaxial connection 304 pass successively through a line. 397, a mobile transmission line 396, and a fixed transmission line 3 98, and reach a coaxial connection 306. The individually fixed column transmission lines 397 and 3 98 have a cross-sectional shape. ring at one end. The U-shaped mobile transmission line 3 96 has a column cross section with its two opposite ends inserted into the fixed transmission lines 397 and 398. Rotation of a drive cable 318 drives a threaded cap 314 formed on one side. right of a medium block 3 92 that moves linearly through the synchronous rotation of a threaded 5 pole 316 formed on the drive cable 318. The middle block 3 92 then drives the moving line 1 3 96 which moves 1inearly. Therefore, the total length of transmission lines 396, 397 and 398 varies and the phase of signals from coaxial connection 304 to coaxial connection 306 also varies.

In U.S. Patent Nos. 3,763,445 and later 4,755,778, the phasers as described above are further refined to desirable utility. Also in relation to Figure 1, lag improvements are: position middle retaining bodies 3 02; adding compensating rings 300 to compensate for discontinuous impedance hopping between fixed transmission line 397 and mobile transmission line 396 and / or between fixed transmission line 398 and mobile transmission line 396; providing conductive plates 394 for orienting and guiding the middle block 392; position a bolt 330 having a spring 32 formed at one end thereof, when the middle block 392 moves toward a left limiting location thereof, spring 332 is pressed and tension

accumulation may prevent the drive cable 318 from immoderate motion and prevent breaker breakage; positioning a spring 328 at a left end of a conductive hole 322, when the middle block 392 moves toward a right limiting location thereof, the spring 328 is depressed and the accumulated tension may prevent the immoderately moving drive shaft 318 from occurring. thereby breaking the phaser; and defining various path length spaces 388 at the ends of the fixed transmission lines 3 97 or 3 98, the 5 ends of the fixed transmission lines 3 97, 3 98 being elastic because of gases 388, thereby providing better contact between the fixed transmission line 3 97 or 3 98 and mobile transmission line 396.

A disadvantage of the phasers as previously described here is that although the ends of the fixed lines 397, 398 are elastic due to the spaces 388, however, after re-duplication, reliable contact between the fixed transmission line 397 or 398 is unlikely. the mobile transmission line 396.

In addition, high power disruptive discharges are likely to occur because of unstable fit of the 3 96, 3 97, 3 98 metal transmission lines, and unwanted contact-induced passive intermodulation products are difficult to avoid. Another disadvantage of laggards as

previously described is that: in order to satisfy the impedance characteristics of the column transmission lines 396, 397, 398, the thickness of the chamber 390 should also be correspondingly increased.

previously described is that: when the phasers are used in a continuously adjustable beam downward tilt base station antenna, several phasers are integratively arranged. Therefore, it is very inconvenient to laminate column transmission lines 3 97, 3 98, and in mold production, mold release in mold processing is also very difficult.

An example of the third disadvantage as set forth above is shown in a published article (Crone, GAE; Rispoli, F.; Wolf, H.; Clarricoats, PJB; "Technology advances in reconfigurable contoured beam reflector antenna in Europe"). re-configurable reflective beam reflector antenna in Europe), Proceeding of 13-th AIAA International Conference on Communications Satellite Systems, 1990, pp.255-2: 63). Fig. 2 is a plan view of a variable power divider according to Fig. 10 of the above article. Referring to Fig. 2, input signals via

A port 51 is split two-way 54b, 54c through an arm 54a of a two-way power divider 54 and then pass U-shaped phasers 55, 56 to connect to two power ports. 3dB 57 directional coupler coupler input 58, 59. When the two-way symmetric "U" -shaped phasers 55, 56 move synchronously in the same direction, one shifter forms a more differential phase and the other one forms a less differential phase. Therefore, based on the well-known network theory of

microwave, a power distribution ratio of tipped directional coupler output ports 52, 53 varies continuously while the corresponding output phase is variable. It is clearly shown that two "U" shaped phasers are used in the example illustrated above, e54b and 54c, or 58 and 59, should be integrally formed, which would inevitably complicate the manufacturing process.

SUMMARY OF THE INVENTION A main object of the present invention is to provide continuous phase adjustment phase shifters that can overcome the disadvantages set forth above in the related techniques and be conveniently used in continuously adjustable beam downward tilt base station antennas. To satisfy the above objective, a lag for

Continuous phase adjustment is provided. The phaser includes a metal chamber and a pair of fixed transmission lines and a mobile transmission line placed in the metal chamber. The mobile transmission line is molded in nU "shape. One end of each of the fixed transmission lines defines a longitudinal channel. Two arms of the mobile transmission line are received in the channels of the fixed transmission lines. The cross section of each one arm of the mobile transmission line is configured as a rectangular shape.

The fixed broadcast in which the channel is defined is set to a rectangular frame with one side of it being omitted.

The cross section of the two arms of the mobile transmission line is configured with a rectangular shape provided with staves and, consequently, the cross section of the fixed transmission line in which the channel is defined is configured as a rectangular frame provided with staves with a from your sides being imitated. To ensure the characteristic impedance of the transmission lines, the mobile transmission line arms are placed in the channels of the fixed transmission lines and do not protrude outside the channel edges.

Moreover, the phaser according to the present invention is further provided with a mechanical drive device. The mechanical drive device includes an isolated portion connected to the mobile transmission line for successively moving the mobile transmission line and continuously adjusting the phase. In order to inhibit passive intermodulation products of

phaser, the mobile transmission line does not contact the fixed transmission lines, so as to ensure that signals can be transmitted in a capacitor coupled mode. A high temperature resistant protective layer

and high power that is made from PTFE (polyfluortraethylene) is coated on a surface of the mobile transmission line.

An upper and lower projection opposite the movable transmission line and the fixed transmission lines are formed on the left and right inner walls of the metal chamber, respectively. Projections extend along the metal chamber in the parallel direction of the signal transmission direction. The upper and lower inner walls of the

Metal that faces the mobile transmission line protrudes out of the upper and lower walls of the metal chamber toward the fixed transmission lines. Compared to conventional designs, the advantages of the present invention are set forth as follows. When fully designed, fixed transmission lines are easily fabricated by mechanical process. When fixed transmission lines are manufactured in the molding process, rectangular frames with their omitted sides may facilitate mold release. Since the cross section of the transmission lines is changed from circular to rectangular, a lag volume is decreased by providing transmission line staves, which may improve their utility. Furthermore, in the present invention, high power passive intermodulation and disruptive discharge products are notably inhibited.

Other new advantages and features will be outlined from the detailed description of preferred embodiment with attached drawings, in which:

BRIEF DESCRIPTION OF DRAWINGS

Fig. 1 is a perspective view of a phaser according to conventional design.

Fig. 2 is a plan view of a conventional successively variable power divider.

Fig. 3 is a perspective view of a phaser according to one embodiment of the present invention showing fixed transmission line connections, mobile transmission line and a metal chamber.

Fig. 4 is an enlarged cross-sectional view of a phaser along a line 4-4 of Fig. 3 showing projections formed on the right and left inner walls of the metal chamber.

Fig. 5 is an enlarged cross-sectional view of a phasor along a line 5-5 of Fig. 3 showing upper and lower inner walls of the metal chamber corresponding to the outwardly projecting mobile transmission line. of the lower inner walls of the metal chamber 5 facing the fixed transmission lines.

Fig. 6 is a cross-sectional view of a phaser according to a second embodiment of the present invention.

Fig. 7 is a cross-sectional view of a phaser according to a third embodiment of the present invention.

Fig. 8 is a cross-sectional view of a phaser according to a fourth embodiment of the present invention. DETAILED DESCRIPTION OF THE INVENTION

Reference will now be made to the drawings to describe in detail embodiments of the present system.

With reference to Figs. 3 to 5, a phase shift phaser of the present invention includes a metal chamber 200, a pair of stationary transmission lines 411, 413 and a mobile transmission line 412 received in the metal chamber 400, and a mechanical drive device (not shown in the drawings).

Each of the fixed transmission lines 411, 413 defines a longitudinal channel at one end of the

same. The cross section of the fixed transmission lines 411, 413 in which the channel is defined is configured with a rectangular U-shaped frame with one side of it omitted (as shown in Fig. 6). The cross section of other portions of the fixed transmission lines 411, 413 is configured as a circular or square shape. Each of the two arms of the mobile transmission line 412 having a rectangular cross section is received in the corresponding fixed transmission line channel 411 or

413. The cross section of the intermediate portion of the mobile transmission line 412 between the two arms is configured as a circular shape or rectangular shape.

Two coaxial couplings 401,402 are formed on two sidewalls of the metal chamber 400, with their conductive cores extending through the sidewalls of the metal chamber 400. The conductive cores of the couplings 401,402 are connected to corresponding ends of the fixed transmission lines 411, 413 well away from the channels. In addition, a mechanical drive device is provided (not shown in Fig. 3, please refer to Fig. 1). The mechanical drive device includes an isolated portion connected to the mobile transmission line 412. In addition, by continuous movement of the mobile transmission line 412, the total length of the

fixed transmission lines 411, 413 and mobile transmission line 412 vary, thereby successively varying the phase between coaxial links 401, 402.

To ensure the impedance characteristic of the mobile transmission line 412 in the same motion as that of the column transmission lines shown in Fig. 1, the mobile transmission line arms 412 are located in the rectangular frames of the fixed transmission lines 411,413. In addition, an upper edge of the line of

Mobile transmission 412 does not protrude from the upper edges of the rectangular frames of the fixed transmission lines 411, 413.

To inhibit phaser passive intermodulation products, mobile transmission line 412 and fixed transmission lines 411, 413 transmit signals in an untouched coupled capacitor mode.

To restrict the position of the mobile transmission line 412 relative to the fixed transmission lines 411, 413 and to obtain a high-power phaser capacity, a high temperature, high power resistant protective layer is coated over the surface of the mobile transmission line. 412. The protective layer is made from polyfluortetraethylene. Accordingly, the size of the U-shaped channels of the fixed transmission lines 411, 413 may be established according to the external size of the mobile transmission line 412 and the thickness of the protective layer.

Referring to Fig. 4, upper and lower projections 421 opposite fixed transmission lines 411,413 and mobile transmission line 412 are formed on inner walls of metal chamber 400, respectively. Projections 421 extend along the metal chamber 400 in a direction parallel to the signal transmission direction. Compared to the inner walls of the conventional metal chamber, projections 421 may facilitate signal coupling isolation between the two parallel fixed transmission lines 411, 413. That is, under an isolated signal condition, the distance between the signal lines. fixed transmission 411, 413 is reduced. Therefore, the volume of the metal chamber 400 is reduced without deteriorating its electrical performance.

Referring especially to Fig. 5, the upper and lower inner walls 423 of the metal chamber 400 correspond to the mobile transmission line 412 projecting outwardly from the upper and lower inner walls 422 of the metal chamber 400 which correspond to the fixed transmission lines 411, 413. Therefore, the increase in characteristic impedance caused by the cross-sectional size reduction of the mobile transmission line 412 and the sudden change in the characteristic impedance caused by transition from the fixed transmission lines 411, 413 to 412 mobile transmission line are offset.

Referring to Fig. 6, a phaser according to a second embodiment of the present invention is shown. In this embodiment, it is described that any side of the rectangular frame defining the WU-shaped channel of the fixed transmission lines 411, 413 may be omitted. For example, according to the first embodiment as illustrated in Fig. 4, the side The right side of the rectangular frame of the fixed transmission line 411 is omitted In addition, the left side of the rectangular frame of the fixed transmission line 411 may also be omitted According to the second embodiment as illustrated in Fig. 6, the upper side of the rectangular frame of fixed transmission line 411 may be omitted In addition, the underside of rectangular frame of fixed transmission line 411 may also be omitted The side of rectangular frame to be omitted is determined by integratively facilitating the manufacture of several lags under special circumstances. Obviously, omissions of rectangular frame sides arranged on an outer side of the lag facilitate the integrative manufacture of laggers.

Referring to Fig. 7, a phaser of 5 according to a third embodiment of the present invention is shown. The difference between the phaser in the third and first modes (with reference to Fig. 4) is that: each of the fixed transmission lines 411 'and the mobile transmission line 412' of the phaser in the third embodiment is provided with staves to form rectangular configurations. Thus, as long as the right edge of the mobile transmission line 412 'does not protrude out of the right edge of the rectangular frame of the fixed transmission lines 411', the lag with desirable electrical performance can be obtained, and therefore the H thickness of the metal chamber 400 is further reduced.

A phaser according to the fourth embodiment of the present invention is provided by further modification of the phaser as described in the second embodiment illustrated in Fig. 6. With reference to Fig. 8,

similarly, the fixed transmission lines 411 and the mobile transmission line 412 are provided with staves in one direction along the thickness H of the metal chamber 400. Thus, as long as the upper wall of the mobile transmission line 412 is not By projecting out of the upper edge of the rectangular U-shaped frames provided with staves, a desired electrical performance offset may be obtained and therefore the thickness H of the metal chamber 400 is further decreased. Phases for continuous phase-phase adjustment as described previously have the advantages of fewer passive intermodulation products, higher power capacity, simpler configuration, smaller volume, simpler manufacturing process 5 and lower manufacturing cost, and, therefore, they may be used in various types of continuously adjustable beam electric downward tilt base station antennas, especially in mobile cellular communications. Although the present invention has been illustrated by

above description of preferred embodiments thereof, and although preferred embodiments have been described in considerable detail, it is not intended to restrict or in any way limit the scope of the appended claims to such details. Further advantages and modifications within the spirit and scope of the present invention will readily appear to those skilled in the art. Accordingly, the present invention is not limited to the specific details and illustrative examples shown and described.

Claims (9)

1. A phase shift phaser characterized in that it comprises a metal chamber (400) and a pair of fixed transmission lines (411, 413) and a movable transmission line (412) fitted to the metal chamber ( 400), the WU-shaped mobile transmission line (412) ", the fixed transmission lines (411, 413) each defining a longitudinal channel at one end thereof, two arms of the mobile transmission line (412) channels in the fixed transmission lines (411, 413), where the cross section of each of the two arms of the mobile transmission line (412) is normally configured as a rectangular shape, and the cross section of the fixed transmission lines (412). 411, 413) wherein the channel is defined to be configured as a rectangular frame with one side thereof being omitted. Offset according to claim 1, characterized in that the cross-section of the two arms of the mobile transmission line (412) is configured as a rectangular shape provided with staves, and the cross section of the fixed transmission lines (411, 413 ) wherein the channel is defined to be consequently configured as a rectangular frame provided with staves with one side thereof being omitted. 25 Offset according to claim 2, characterized in that the movable transmission line arms (412) are arranged in the fixed transmission line channels (411, 413) and do not protrude outside the channel edges; A phaser according to any one of claims 1, 2 or 3, characterized in that the phaser further comprises a mechanical drive device, the mechanical drive device comprising an isolated portion connected to the mobile transmission line (412) of successively moving the mobile transmission line (412) and continuously adjusting the phase, Offset according to claim 4, characterized in that the mobile transmission line (412) does not contact the fixed transmission lines (411, 413) so that the signals are transmitted in a coupled mode of capacitor. Offset according to claim 5, characterized in that a movable transmission line surface (412) is covered with a high temperature and high power resistant protective layer. Offset according to claim 6, characterized in that the protective layer is made from polyfluortetraethylene. Offset according to claim 7, characterized in that upper and lower projections (421) opposite the movable transmission line (412) and the fixed transmission lines (411, 413) are formed on the inner right and rear walls. To the left of the metal chamber (400), respectively, the projections (421) extending along the metal chamber (400) in a direction parallel to the direction of signal transmission. Offset according to claim 8, characterized in that the upper and lower inner walls (423) of the metal chamber (400) corresponding to the movable transmission line (412) protrude from the upper and lower walls. (422) of the metal chamber (400) corresponding to the fixed transmission lines (411, 413).