FI126131B - RF filter - Google Patents

Description

RF filter

Background of the Invention

The invention relates to an RF filter.

RF filters, or radio frequency filters, are used, for example, in connection with RF equipment used in base stations of a cellular network, such as a transmitter, receiver or transceiver, in particular amplifiers contained therein as filtering and matching circuits.

Resonator-type filters include a housing structure having one or more compartments whose shape is defined by the wall structure of the housing structure.

The housing structure compartment may typically have an inner conductor attached to the bottom of the compartment, or cavity, called a resonator or resonator pin, the common structure being a coaxial resonator wherein the inner conductor, or resonator, is coaxial or coaxial with the surrounding compartment or cavity. The metal housing compartment and the metal inner conductor in the compartment together form a resonant circuit. Particularly in more complex high-frequency filters, the housing structure is a multi-compartment and each compartment has its own internal conductor or resonator, thereby forming a plurality of resonant circuits which, by suitable coupling, provide the desired frequency response or barrier.

In an RF filter, a transmission line can be used inside the housing structure, which supplies an adjacent compartment with an RF signal from a signal port or the like attached to the end of the housing structure. That transfer line has to be attached to something, and it is known to use a vertical support arm that attaches to the bottom of the filter housing, and it is also known to use a projection molded on the wall of the housing structure to support the transfer line. These structures, of course, allow the transmission line to be supported, i.e. fastened, but they are laborious in terms of manufacturing and / or filter assembly.

Brief Description of the Invention

It is therefore an object of the invention to provide an RF filter so that the above problems can be solved or alleviated.

The object of the invention is achieved by an RF filter, which is characterized by what is stated in the independent claim. Preferred embodiments of the invention are claimed in the dependent claims.

An advantage of the invention is to provide a reliable anchorage or support point for a transmission line in an easily manufactured manner.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described in more detail in connection with some embodiments, with reference to the accompanying drawings, in which: Figure 1 shows an RF filter viewed from the direction of the filter housing cover; Figure 2 shows a side view from the long front side of the filter housing; Figure 4 shows the filter of Figure 3 with the lid and the front side, Figure 5 shows the partition wall of the housing with the bent support projection.

DETAILED DESCRIPTION OF THE INVENTION

Referring to the figures, which is an RF filter F, the filter F can be used in connection with or connected to an RF device such as a transmitter, receiver, transceiver or amplifier. The RF device may be, for example, a radio unit or module of a base station in a cellular radio network.

The filter F has signal ports SP1, SP2, the signal ports can be connected by cables connecting the filter F to the antenna and, for example, to the transceiver. The short cables shown in Figure 3 at the signal ports SP1, SP2 may connect the filter to the coaxial connectors attached to the walls of the outer housing (not shown) surrounding it.

The filter comprises a housing structure C with a wall structure W with a bottom B underneath and a lid T. The housing structure C, i.e. its wall structure W, base B and lid T are made of conductive metal, for example copper or aluminum coated with silver or other conductivity enhancing material.

The RF filter shown in the figures is a coaxial resonator filter, i.e. it has one or more compartments CPA1-CPA4 and has internal compartments R1-R4, respectively, resonators or resonator pins which are parallel or coaxial with the compartment direction of the housing C, i.e. in a perpendicular direction. Each housing cavity CPA1-CPA4 together with its resonator R1-R4 forms a resonant circuit, and adjacent resonant circuits together form a filter having the desired attenuation curve. For example, the filter may be a bandpass filter. The resonators R1-R4 are fastened with screws to the bottom B of the housing C.

The lower ends of the resonators R1-R4, i.e. the lower parts of the resonators in Fig. 1, are thus short-circuited to the bottom B of the housing C, which at the same time acts as a common ground for the resonators R1-R4. In Figure 1, the tops of the resonators R1-R4 are so-called. free ends which are galvanically detached from housing C, in particular housing T. T. In the situation of Figure 1, the length of the resonators is about a quarter of a wavelength.

The wall structure comprising the housing C, which is thus between the bottom B and the cover T, comprises sides S1-S2, ends E1-E2, and partitions W1-W3 between the compartments. Thus, in the four-compartment enclosure structure, there are three partitions W1, W2, W3 between the compartments CPA1, CPA2, CPA3, CPA4, the role of the partitions is to separate the compartments and thus the resonant circuits by preventing excess capacitive coupling between the free ends of resonators R1-R4. In Fig. 2, the longest side S2 of the wall structure W of the housing C is closest to the viewer, so that the structures behind the side S2 are shown with a dashed line.

The filter comprises a signal port SP1 at the end of the housing E1 and an RF transmission line TL associated with that signal port, each RF transmission line TL being arranged to transmit an RF signal to the RF filter sections CPA1-CPA4. At one end of the filter, the filter E2 comprises a second signal port SP2. The signal port SP1 may communicate with the RX // TX device, i.e. the transceivers, in particular the amplifier it contains. Signal port SP2 may be connected to an antenna cable. The other end of the transmission line TL, i.e. the right end of Figure 3, is connected to the second signal port SP2.

The transmission line TL is supported on the wall structure of the housing C. To support the RF transmission line TL, the wall structure of the housing C comprises a support projection SU1-SU4 bent from the wall of the wall structure W to which the transmission line TL is secured by an insulating fastener IS1-IS4. Fig. 3 shows a wall-angled support projections SU1-SU4, which are outer branches of TL1-TL4 that branch from the main line ML of the transmission line TL. Specifically, a wall-bent support brace, such as SU1-SU4, is a support bracket for supporting the free end of the outer branch branch SU1-S4, which is branched from the main line of the transmission line, since the free end of the brace branch is most exposed to vibration. In Figure 3, the bent support projection SU4 remains essentially invisible below the protrusion leg TL4 of the transmission line TL.

The wall-bent support projections SU11-SU13 are for supporting the TL main line ML. The transmission line TL, in particular the main line ML of the transmission line, is secured to those bent support projections SU11-SU13 via an insulating fastener IS11-IS13.

The proximity of the transfer line TL from the main branch ML of the transfer line extending from the resonators R1-R4 to the resonators TL1-TL4 can be considered as coupling projections for capacitive coupling between the resonators R1-R4 and the transmission line T1. In order to enhance and adjust the capacitive coupling, the protruding branches TL1-TL4 of the transmission line TL comprise coupling parts CP1-CP4 which, for example, may be bendable plate surfaces, although other forms are possible. The strength of the coupling between the resonators R1-R4 and the transmission line TL is influenced by the size and distance of the coupling parts CP1 to CP4 from the resonator. The coupling parts CP1 to CP4 are most clearly shown in Figure 3.

In order to remain capacitive in the coupling between the resonators R1-R4 and the transmission line TL, in particular the coupling branches TL1-TL4 comprising the resonators R1-R4 and the transmission line TL, the coupling parts CP1-CP4 in the C, or body.

It will be appreciated that in one embodiment, a wall-extended support projection, such as SU3, is at the edge of the wall because it is more easily formed therein than in the middle of the wall.

In order for the transmission line TL to settle and lean easily on a suitable height, the wall-bent support projection, such as SU3 in Figures 2, 3 and 5, is positioned in wall W3 so as to be near resonator cover B at the top of the compartment. In this case, a support projection, such as SU3, is bent from the wall at the free end or capacitive end of the resonator, such as R3, at a distance from the cover B, also placing the transmission line TL in the same area.

It is found that a wall-bent support projection, such as SU2, is in the partition W1 between the RF filter compartments, such as CPA1, CPA2. The wall-bent support projection SU3 is located in the partition W3 between the RF filter sections CPA3, CPA4.

The wall-bending support projection SU11 is located in the partition W1 between the filter sections CPA1, CPA2. The wall-facing support projection SU12 is located in the partition W2 between the filter sections CPA2, CPA3. The wall-angled support projection SU13 is located in the partition W3 between the filter compartments CPA3, CPA4.

With reference to the foregoing, in one embodiment, at least two bent support projections for the transmission line TL are provided on the same wall as W1, W3. In one embodiment, the same wall, such as partition W1, W3, has a bent support projection for both the main line ML of the transmission line and a branching protrusion thereof, such as TL2, TL3. It will be appreciated that a wall such as a partition W1 has a bent support projection SU2 for the outermost branch TL2 and a bent support projection SU11 for the main branch ML of the transmission line TL. Similarly, a wall such as a partition wall W3 has a bent support projection SU3 for the transverse branch TL3 and a bent support projection SU13 for the main branch ML of the transmission line TL

Referring to Figure 5, support projections such as SU3 are easiest to bend into the partition body before the partition body is inserted between the long sides S1, S2 of the housing C. The partition wall W3 has a groove defining the width of the support projection SU3, which allows the support projection to be bent. The support projection is bent substantially perpendicularly, i.e. at an angle of about 90 degrees to the plane of the partition surface. Advantageously, the plane surface of the support projection SU3 is parallel to the transmission line TL, whereby the fastening with the insulating fastener IS3 is easiest. The insulating fastener IS1-IS4, IS11-IS13 may be, for example, a plastic screw for which the support projection has a threaded housing THR or the like.

Housing C with its components B, T, W, W1-W3 is a conductive metal such as copper or aluminum plated with silver, for example.

It will be obvious to a person skilled in the art that as technology advances, the basic idea of the invention can be implemented in many different ways. The invention and its embodiments are thus not limited to the examples described above, but may vary within the scope of the claims.

Claims (10)

An RF filter comprising a housing (C), wherein the wall structure (W) between the housing bottom (B) and cover (T) defines at least one compartment (CPA1-CPA4) and said RF filter has compartment-specific resonators (R1). R4), and which RF filter comprises a signal port (SP1) and in its connection an RF transmission line (TL), which RF transmission line is arranged to transmit an RF signal to the RF filter compartments (CPA1-CPA4), characterized in order to support the RF transmission line, the wall structure (W) of the housing (C) comprises one or more curved support projections (SU1-SU4, SUUSI! 13) bent to the wall structure to which the transmission line (TL) is attached via an insulating fastener (IS) . RF filter according to claim 1, characterized in that the support projection (SU1-SU4, SU11-SU13) bent from the wall is provided at the edge of the wall. RF filter according to claim 1 or 2, characterized in that the support projection (SU1-SU4, SU11-SU13) which is curved from the wall is so placed in the wall that it is close to the resonator lid in the upper part of the compartment. RF filter according to claim 1, 2 or 3, characterized in that the support projection (SU1-SU4, SU11-SU13) bent from the wall is adjacent the free end of the resonator (R1-R4) away from the cover (B). RF filter according to one of the preceding claims, characterized in that the support projection (SU1-SU4, SU11-SU13) which is bent from the wall is in a partition wall (W1, W2, W3) between the sections of the RF filter. RF filter according to one of the preceding claims, characterized in that the same wall (W1) has at least two curved support projections (SU2, SU11) for the transmission line (TL). RF filter according to any one of the preceding claims, characterized in that the support projection (SU1-SU4) bent from the wall is a support projection for supporting the projection branch (TL1-TL4) branched from the transmission line (TL) main line (ML). . RF filter according to claim 7, characterized in that the support projection (SU1-SU4) bent from the wall is a support projection for supporting the free end of the projection branch (TL) branch line (ML1-TL4). RF filter according to one of the preceding claims 1-6, characterized in that the support projection (SU11-SU13) bent from the wall is a support projection for supporting the main line (ML) of the transmission line (ML). RF filter according to claims 7 and 9, characterized in that the same wall (W1) has a curved support projection (SU2, SU11) for both the main line (ML) of the transmission line and for the branched projection branch (TL2, TL3).