SE506106C2 - Amplifier for antenna and using integrated dual duplex filters - Google Patents

Abstract

The antenna amplifier has an antenna connection (1), and a transmitter connection (2) coupled to same via a first bandpass filter (Tx) for transmitter frequencies. A receiver frequency amplifier input is connected to the antenna connection via a second bandpass filter (Rx1). The amplifier has an output that is connectable to the receiver. The filters are mounted in a common elongated cavity and include comb-line type resonators arranged in rows along a cavity mean line. The antenna amplifier has connector pins at the two mutually approaching ends of the two filters and at the two outer ends.

Description

15 20 25 30 35 566 106 2 amplifiers. On both sides of the central filter for the transmitter band are connections for connection to an antenna resp. to a descent to a fixed station. A device is also described in which the first and the second filter for the receiving band are arranged side by side in their respective cavities, with the filter for the transmitter band mounted perpendicularly opposite it, in a separate cavity and in which the connection between them takes place via apertures and connecting first resonators.

An antenna amplifier of the intended type is intended to be mounted up in a tower, which can be 60 meters high, and where service takes place by the serviceman climbing a ladder and working outdoors. It is therefore an object of the invention that an amplifier of the intended type should be manageable, easily replaceable and efficient. The antenna amplifier must also be able to be mass-produced at a reasonable price, taking into account the large number needed for expanded mobile phone traffic. It should be easy to connect, tender and as small and light as possible.

An important point of view is that one wants to be able to make full use of the possibilities provided by integrated circuits, if they can directly, without for example coaxial connectors, with connection losses and distortions that are as small as possible, be connected to the filter devices.

These objects are achieved according to the invention by an antenna amplifier of the type stated in the characterizing part of claim 1.

Two essential features in true combination contribute to this: The construction of comb-line filters with connection via coupling pins for its inputs and outputs and housed in a horseshoe-shaped folded cavity formed by a metal housing and an amplifier on a printed circuit board, with the input connected to the filter via a perpendicularly incoming connection pin inserted towards the circuit board. Due to this construction, a special loss arm BNsDoc1o 506 106 3 connection is achieved at the input, especially in comparison with a connection made via a coaxial connection to a separate amplifier. By combining the printed circuit board into a rigid metal structure which occupies the filter itself, the combination is completed.

The inventive combination can be used either with a combination of common up and down, or with separate up and down. In the former case, filters are required not only to separate the receiver signal but also to carry the amplified receiver signal to the common up and down line.

For the combination with common up and down line, a filter device is arranged according to a variant where two filters arranged in parallel have adjacent inputs and these are also mutually connected to another filter, without the need for hybridization between Coax Cavity and Comb Line.

It then turns out according to the invention to be possible to join the three filters and the said two inputs / outputs into a single cavity with two parallel straight portions and a bent, joining portion which occupies the middle filter.

Among the things that one wishes to improve are the insulation between the transmitter and receiver bands, reducing the losses in the Tx path and reducing the non-linearity in the transmitter band, something which is suitable for reducing the occurrence of so-called spurious intermodulation products, the smallest possible noise factor for the reception and the largest possible effective radiation for the transmission as well as low weight and size. The amplifier itself is then mounted in a printed circuit board located next to the cavity, and the connection is made by connection pins, either directly with inductive connection or with capacitive connection, to wires in the circuit board of type microstrip or stripline and with proper adaptation.

In mobile communication, normal frequency bands are at 1700 - 2000 MHz resp. at 800 - 1000 Mz. The frequency distance between BNSDOCIDI 10 15 20 25 30 35 506 106 4 transmitter and reception bands is generally 20 MHz. These are frequency ranges suitable for the application of microwave technology.

The invention will now be further elucidated in exemplary embodiments in connection with the figures.

Fig. 1 shows a schematic diagram of an antenna amplifier for duplex operation, in accordance with the prior art.

Fig. 2 shows a schematic diagram of an antenna amplifier with a combined filter according to the basic principle of the invention.

Pig. 3 schematically shows a folded dual duplex filter in accordance with the principles of the present invention.

Figs. 4A, 4B and 5 show perspective views of a constructed filter.

Fig. 6 A - C show a dimensioned drawing of an example of a dual duplex filter.

Figs. 7 and 8 show examples of inductive connection to a circuit board.

Figs. 9 A, B and 10 A, B show frequency curve diagrams for an adjusted copy of the embodiment shown in Figs. 6 A - C, with amplifier disconnected resp. with working amplifiers for signals coming from the antenna side.

Fig. Fig. 11 A, B and 12 A, B show adaptation and transmission curves for the same embodiment.

Fig. 13 shows a sketch made partly as an exploded view showing the general construction of another embodiment of the invention.

Schematic Fig. 1 shows a known antenna amplifier connected between an antenna and a tower (Tower Mounted low noise Amplifier, TMA). By means of two duplex filters, two line branches are obtained, one Tx for the transmitter signal, the other Rx for the received signal, which can thus be separated by filters due to the fact that they are within different frequency bands.

Such broadband filters are usually composed of resonators with slightly different tuning frequencies in so-called comb-line- BNSDOCID: 10 15 20 25 30 35 506 106 5 filter. Obviously, in such a configuration, four such filters are needed, namely in each duplexer a bandpass filter for the Tx and one for the RX frequency band. The low noise amplifier LNA is connected in the Rx branch.

In accordance with a basic principle of the invention, stated in Swedish patent application 9502604-3 of 14 July 1995 and not generally available, one of four filters is now eliminated, in accordance with the diagram in Fig. 2. The transceiver connection BTS will thereby be able to deliver transmitter power to the antenna only via Tx, tuned to its frequency band. The received signal of the antenna can only travel via Rx1 to the input of the low-noise amplifier LNA, whose output signal via the filter Rx2 passes to BTS.

A comparison with Fig. 1 shows that in addition to the elimination of a filter, the Tx path also reduces from 4 connection points to 2. As far as the Tx path is concerned, the connection losses are thus halved in principle. This achieves an improvement in ERP (Effective Radiative Power).

For frequencies within the band 1700 - 2000 MM: the length of a filter box with a straight cavity can be kept at a reasonably moderate length, but for the band 800 - 1000 Mmz the length is structurally approximately twice as large. There is therefore an interest in being able to fold the same already to shorten the length. The connections 3 and 4 for the amplifier LNA then come closer to each other, which further facilitates their connection to one and the same circuit board. in a development of this basic idea, the filter combination in Fig. 3 has emerged. The connection elements for antenna resp. transmitter receivers are arranged together with the Tx filter in a curved part of a cavity, while the Rx filters are mounted in their respective parallel straight part of the same cavity, which constitute extensions on either side of the bend, which occupy 180 °.

The connecting elements to the transmitter and antenna are located approximately at the ends of the bend. The coupling elements 3 and 4 at the opposite ends of the cavities BNSDOCID: 10 15 20 25 30 35 506 106 6 now end up at a comfortable distance from each other, which facilitates an integrated connection of an amplifier on a circuit board mounted on the outside of the filter construction.

Construction of combline filters of the type according to the invention largely avoids analytical treatment. The construction therefore conveniently takes place by simulation in a computer. In general, one then begins with determinations and successive calculations to determine the coupling coefficients, ie. the distances between the successive resonant circuits, in order to obtain a suitable bandwidth.

This determines the mechanical construction. The filters are then adjusted with the help of a network analyzer.

As mentioned in the introduction, the isolation between the frequency bands Tx and Rx is one of the important factors. In principle, this can be achieved either by filters with a high number of poles, which, however, is associated with correspondingly high losses, or by using fewer poles and introducing extra zeros. Therefore, in the construction according to Fig. 3, notches N have been inserted at the connecting elements 3 and 4, which act as narrow-band band-blocking filters, set to a tangent frequency between the Rx and Tx bands. This increases the steepness and separation. Since these elements are lossless in resp. passband, filter losses are minimized.

As mentioned, the connection elements 3 and 4 have the function of connecting the signal between the LNA and the Rx filter, but they are used simultaneously for connecting the notches N. Another important advantage of this type of connection element is that the third order intermodulation products (IM3) are minimized. IM3 is a measure of the linearity of the device.

In Pig. 4A shows a perspective view of an opened filter according to the invention, and Pig. 4 B shows its removed cover from the inside. Pig. 5 shows the "underside" not shown in Fig. 4A with a circuit board with a partially only schematically shown amplification circuit. The bent cavity, with a cross section of 21 x 36 mm, is made of solid aluminum and silver-plated on BNsDomD; 10 15 20 25 30 35 506 106 7 ytan. The connections for antenna and BTS, as previously designated 1 and 2, are made with coaxial contacts 1 'and 2' while adjusting to 50 ohms via bent tenets, which enter the cavity and when the cover is fitted electrically and mechanically screwed to the cover via hole 1 " respectively 2 ". From the bottom of the cavity in Fig. 4A protrude pillars 10 for Tx and II for Rx, which act as the inductances of the resonances, and from the cover come trim screws 12, which with the upper surfaces of the columns form adjustable capacitances for the resonant circuits.

The notches N also have capacitance determining screws 12 (partially obscured in Fig. 4B). The sockets 3 and 4 (Fig. 3) are arranged through pillars 13, which are mounted in the cover (Fig. 4B) and exit through holes in the bottom (Fig. 4A) to circuit board connections 14, and are soldered there. Figs. 4A and 4B show the device prior to the manufacturing step.

These solder points 14 are shown in Figs. 5 on the right side of the circuit board 20. The circuit board 20 is made of a plastic material with low losses and on the underside provided with a ground plane (not shown), which makes it possible to build circuits in microstrip and connect the connections directly to the filter for the amplifier LNA. and outputs. This connection is shown in Figs. 6 and 7. The ends of the columns 13 are tapered at 15 and drawn through a hole received through the circuit board 20 (and through the ground plane) and on the other side connected via a solder joint 14 to a microstrip line 21. Through such a passage can be adapted to 50 ohms, and a possible phase error can be regulated with a surrounding earth path 22 shown in Fig. 8 and a capacitor (not shown). On the circuit board shown in Fig. 5, the existing amplifier LNA has not been drawn but only indicated by dashed symbols, taking into account that the amplifier itself is known to the person skilled in its type. - This connection between the filter and the amplifier circuit is of the inductive type - but capacitive connection is also possible.

EXAMPLE A specific embodiment of a filter combination of the type indicated can be seen in mm dimensioned Fig. 6 AC, which shows views of BNSDOCID: <5E7__5O6106C2_l> 10 15 20 25 30 35 506 106 8 the device shown in Figs. 4A, 48 and 5, from which complete dimensions can be obtained from a working example.

A filter according to the configuration in Fig. 3 was thus constructed, although with three resonators in the Tx part and resp. 6 resonators in the Rx parts. The intended frequency band limits were for Tx 1.850 - 1.875 GHz and for Rx 1.755 - 1.780 GHz.

Fig. 9 A, B resp. 10, A, B show the performance of the amplifier design. The A-curves show terminal adaptation, the B-curves TMA's transmission characteristics.

One can in Pig. 10 B in particular notice that signals in the receiver band are amplified by just over 12 dB. Fig. 9 B shows that if the function of the amplifier fails, the construction is harmless, in that the signals pass undisturbed through the filter construction.

Figures 11A and B and Figures 12 A and B show filter curves for resp. one Rx and Tx path. The A-curves show terminal adaptation, The curve in Fig. 11 B shows the transmission between connections 1 and 3 (which is similar to the one between 2 and 4, which is therefore not shown), while Fig. 12 B shows the transmission between 1 and 2. The curves show that very high attenuation values are achieved.

The amplifier is a low-noise amplifier built on a circuit board, with the high precision in adaptations etc. which is possible with this technology. Through such a connection, the losses are minimized and an optimized low noise factor can be obtained for the receiving band Rx.

As mentioned in the introduction, the invention can also be applied to the case where separate lines are used for conduction of transmitter power and conduction of received signals. A schematic view in Pig. 13 shows such a construction. For a better understanding, the cavity receiving the filter has only been drawn a bottom surface 30 with resonator pins 11 and notch pins N attached thereto, together with the lid 31 next to it. Through the filter between the coupling pins 1 and 2, the BNSDOCID: BNSDOCID '506 106 9 antennas. The received signal coming from the antenna goes via the curved filter provided with six resonator poles to the disconnection pin 13, which in the same way as in Figs. 7 and 8 disconnects the signal to the amplifier mounted on the circuit board 20. Fig. 14 shows more clearly how this disconnection with adaptation takes place to a standardized coaxial contact. The lid shows screws 32, which in the assembled apparatus are screwed into the connecting pins 1, 2 and 13. The lid is of course also screwed into the walls (not shown) of the cavity, which, as shown for the first described embodiment, is milled out. an aluminum piece and internally silvered.

Each resonator pin 11 is supplemented in the lid by a trimming screw 12 screwed through an opposite hole, which is locked with a lock nut 33. Although only such a set is shown, it will be appreciated that there is one for each resonator and one for each notch resonator N.

Here you get a very practical, monolithic device, which thanks to the horseshoe-curved filter construction obtains manageable length. It is possible, as shown, to place all three connections on the same side in a row as coaxial connectors at a mutual distance that allows convenient installation and removal of coaxial cables.

WSOB 106C2 I _>

Claims (7)

10 15 20 25 30 35 506 106 10 Patent claims Antenna amplifier with an antenna connection, an input (2) connected to the antenna connection via a first bandpass filter (Tx) for transmitter frequencies (2) and an input to the antenna connection via a second bandpass filter (Rx: Rxl) for receiver frequencies connected to an amplifier for receiver frequencies output which is connectable to a receiver, characterized in that the bandpass filters consist of comb-line filters having their resonators housed in a horseshoe-shaped folded cavity formed by a metal housing, and the amplifier is built in a circuit board in microstrip or or stripline technology and with an input adapted connected via a connecting pin inserted perpendicularly to the circuit board (Fig. 7), and from the fact that at both ends of the cavity are arranged their respective connecting pin (3, 4). Antenna amplifier according to Claim 1, characterized in that a notch resonator (N) is arranged at both ends of the cavity, outside the connecting pins (3, 4) arranged there. Antenna amplifier according to claim 1 or 2, characterized in that two comb-line filters are arranged in the horseshoe-shaped cavity, a first (Tx), for transmitter frequencies, fully occupied in one leg of the horseshoe shape, a second (Rx) for receiver frequencies, occupied in the other part of the horseshoe mold, including the second leg and the bend, the second filter having a larger number of resonators than the first. Antenna amplifier according to claim 1 or 2, characterized in that three combline filters are arranged in the cavity-folded cavity, each with a bandpass filter for receiver frequency (Rx) at the horseshoe shape resp. legs and a bandpass filter for transmitter frequency at its bend, with antenna resp. down-connecting connecting pins (1,2) between the comb-line filters and next to the ends of the legs are each aNsDoc | o; 10 15 20 25 506 106 ll connection pin (3,4) for connection to the circuit board-mounted amplifier resp. input and output. Antenna amplifier according to one of the preceding claims, characterized in that the connection to the input of the circuit board-mounted amplifier is made with a connection pin (13) which is attached with one end to a wall in the cavity and its other end is extended through a hole in an opposite wall in the cavity and is in contact with an impedance-adapted circuit board conductor (21) arranged in the circuit board, constituting an inductive connection to the circuit board conductor. Antenna amplifier according to any one of claims 1 - 4, characterized in that said connecting pin is attached at one end to a wall in the cavity and via a hole in an opposite wall in the cavity capacitively connected to an impedance-adapted circuit board conductor arranged in said circuit board. Antenna amplifier according to one of the preceding claims, characterized in that the said antenna resp. The downwardly connecting coupling pins are each connected to a coaxial connection. BNSDOCID: