EP2071660A1 - High-pass filter - Google Patents

Abstract

The high pass filter has a signaling line, which has multiple capacitances connected in series. Multiple inductances are connected between the signaling line and a ground wire. The signaling line has an inner conductor (32) and the ground wire has an outer conductor (30). The inner and outer conductors are coaxial. An insulation layer (76) is arranged between the inner conductor and the outer conductor. Inductances are formed as discrete components (38,39,40,41) and arranged at some distance from each other. Impedances are connected between the discrete components.

Description

The invention relates to a high-pass filter comprising a signal line with a plurality of capacitors connected in series and a ground line, wherein a plurality of inductances are connected between the signal line and the ground line.

Such high-pass filters are used, for example, in communications technology, in particular in mobile radio technology. For example, they may be connected between an antenna and a signal processor and ensure that signals within a first frequency range of relatively low frequency are very much attenuated, whereas signals within a relatively high frequency second frequency range experience only minimal attenuation. Thus, the signals of the first frequency range can be virtually hidden.

High-frequency signals are usually transmitted by means of coaxial cables, which have an inner conductor and an outer conductor surrounding the inner conductor, an insulation layer being arranged between the inner conductor and the outer conductor. In connection with the configuration of a low-pass filter, in which therefore signals with a relatively low frequency experience only a very low attenuation, whereas signals with a high frequency are subject to a very strong attenuation and are therefore practically hidden, was in the DE 32 07 422 A1 already proposed to postpone the distance between the inner conductor of the insulating layer determining additional elements on the inner conductor, which increase its capacity and thereby between the inner conductor and the outer conductor form a capacitor, whereas the inner conductor itself forms an inductance in the region between two capacity-increasing additional elements. As a result, a low pass can be formed in a structurally simple manner in coaxial design.

Object of the present invention is to design a high-pass filter of the type mentioned in coaxial design.

This object is achieved according to the invention in a high-pass filter of the generic type in that the signal line forms an inner conductor and the ground line forms an outer conductor of a coaxial conductor, between which an insulation layer is arranged, and in that the inductors are configured as discrete components spaced apart from one another at least one impedance is switched.

At least two inductors are used in the high-pass filter according to the invention, which are formed as discrete electrical components, via which the inner conductor is in electrical connection with the outer conductor. To ensure that the inductors do not significantly affect each other, they are spaced apart with the interposition of at least one impedance. In addition to the inductors and the at least one impedance, at least two capacitors are used, which are connected in series with one another in the inner conductor. The high-pass filter according to the invention thus has at least two LC elements connected in series and additionally at least one impedance which ensures a decoupling of the two inductances and in series with the capacitances is switched. It has been found that this can be configured in a structurally simple manner, a high-pass filter in a coaxial design.

Preferably, at least one inductance is designed as a spiral-shaped coil. This can extend from the inner conductor radially outwards in the direction of the outer conductor. It can be provided that the outer end of the spiral coil is directly connected to the outer conductor, so that there is a galvanic connection between the spiral coil and the outer conductor.

Of particular advantage with regard to a cost-effective design of the high-pass filter is when the inductances are identical in terms of their electrical and / or mechanical properties.

The at least one impedance arranged between the inductors is preferably designed as a line section of the inner conductor. Discrete electrical components for providing impedance can thereby be dispensed with.

A further reduction in manufacturing and assembly costs is achieved in an advantageous embodiment in that the capacitors connected in series to one another in the inner conductor are identical in terms of their electrical and / or mechanical properties.

It is particularly favorable if the capacities are designed as plate or tube capacitors. Pipe capacitors have at least one tubular or sleeve-shaped, electrically conductive layer as well as a likewise tubular or sleeve-shaped dielectric surrounding a further electrically conductive layer.

It has proved to be advantageous if the high-pass filter has at least one pi-element with a pair of inductances, which are connected between the inner and the outer conductor, wherein between the two inductances in the inner conductor, a first capacitance, an impedance and a second Capacitance are connected in series with each other.

Preferably, the two capacitances of the at least one Pi element are identical in their electrical and / or mechanical properties. In particular, it can be provided that the two capacitances of the at least one Pi element are designed as plate or tube capacitors.

The impedance connected between the two capacitances of the at least one pi-element is preferably designed as a line section of the inner conductor.

It is advantageous if the line section of the inner conductor interconnecting the two capacitances of the Pi element carries a front and a rear, electrically conductive contact sleeve which receives a dielectric insulating sleeve, into which an end section of a further line section of the inner conductor is inserted. In each case, a contact sleeve in combination with an insulating sleeve and an end piece of a further line section forms one of the two series-connected capacitances of the Pi element.

It is particularly advantageous in this case if the front and the rear contact sleeve are integrally connected to the line section of the inner conductor interconnecting the two capacitors connected in series with each other. Thereby, the mounting of the high-pass filter can be simplified.

In a preferred embodiment of the high-pass filter according to the invention, this has two Pi elements which are connected to one another via an impedance. Each of the two Pi elements has two inductances each, which are connected to each other via two capacitors and one impedance.

The impedance connecting the two pi-members together is favorably designed as a line section of the inner conductor.

It is particularly advantageous if the two Pi elements are identical in terms of their electrical and / or mechanical properties, because this can reduce the manufacturing and assembly costs of the high-pass filter.

In order to improve the edge steepness of the high-pass filter, it is favorable if a capacitor is connected in series between at least one inductance and the outer conductor. The inductance forms a series resonant circuit in combination with the series connected capacitance. This makes it possible to attenuate signals in the range of the resonant frequency of the resonant circuit very strong.

Preferably, a capacitor is connected in series between each inductance and the outer conductor. This allows a galvanic connection between the inductors and the outer conductor are avoided. This in turn results in a simplification of the mechanical construction of the high-pass filter.

The avoidance of a galvanic connection between the inductors and the outer conductor has the additional advantage that between at least one inductor and the capacitor connected in series with this a connection for feeding and / or tapping a supply or control voltage can be provided. As a result, not only a high-frequency information signal, in particular a communication or data signal, can be transmitted via the high-pass filter, but additionally a supply voltage, in particular a DC voltage or else a control voltage can be fed or tapped. In particular, a signal for the digital remote control of an antenna can be used as the control voltage. Such a signal may be fed and / or tapped at a node between an inductor and the capacitor connected in series with it. For this purpose, it is only necessary to dimension the capacitance connected in series with the inductance in such a way that it represents a high resistance between the inductance and the outer conductor with regard to the supply and / or control voltage which is low compared to the information signals.

Preferably, the high-pass filter, for example by means of connectors or by means of cable connections or a combination of both, be inserted into a coaxial transmission line.

The high-pass filter according to the invention preferably has a rigid housing part, which is formed by the outer conductor. Preferably, the housing part is made of metal.

The insulation layer arranged between the inner conductor and the outer conductor in a preferred embodiment, the housing part on the inside at least partially lined. The insulation layer can be made, for example, from a PTFE material (polytetrafluoroethylene material).

In order to keep the manufacturing and assembly costs of the high-pass filter according to the invention low, it is favorable if the insulating layer forms a dielectric of at least one capacitance, which is connected in series with an inductance.

It is particularly favorable if at least one inductance of the high-pass filter forms a spacer between the inner conductor and the outer conductor. The use of additional spacers over which the inner conductor is arranged concentrically to the outer conductor and at a distance therefrom can thereby be at least reduced.

The high-pass filter according to the invention is preferably used for the transmission of mobile radio signals. It can be provided that by means of the high-pass filter signals in the range of 800 MHz to about 960 MHz are subject to an attenuation of more than 30 dB, in particular an attenuation of at least 40 dB, whereas mobile radio signals in the range of 1700 MHz and 2700 MHz are practically not attenuated ,

Figur 1:

einen Längsschnitt eines Hochpassfilters;

Figur 2:

eine Schnittansicht längs der Linie 2-2 in Figur 1;

Figur 3:

ein Schaltbild des Hochpassfilters aus Figur 1 und

Figur 4:

eine Veranschaulichung der Durchlassdämpfung des Hochpassfilters aus Figur 1 in Abhängigkeit von der Frequenz eines zu übertragenden elektrischen Signales.

The following description of a preferred embodiment of the invention serves in conjunction with the drawings for further explanation. Show it:

FIG. 1:

a longitudinal section of a high-pass filter;

FIG. 2:

a sectional view taken along the line 2-2 in FIG. 1 ;

FIG. 3:

a circuit diagram of the high-pass filter FIG. 1 and

FIG. 4:

an illustration of the transmission loss of the high-pass filter FIG. 1 depending on the frequency of an electrical signal to be transmitted.

In FIG. 1 schematically shows a longitudinal section of a total occupied by the reference numeral 10 high-pass filter having a central filter part 12 and an input-side connector 14 and an output-side connector 16. The input-side connector 14 is connected to the in FIG. 3 shown signal input 18 of the filter part 12 is connected, and the output-side connector 16 is connected to the in FIG. 3 shown signal output 20 of the filter part 12 connected. The two connectors 14 and 16 have a central contact socket 22 and 24, which is surrounded by a contact sleeve 26 and 28, respectively. About the input-side connector 14, the filter part 12 can be connected to a known per se and therefore not shown in the drawing input line, for example, can connect between a mobile phone antenna and the filter part 12. With the help of the filter part 12, the received signal filtered and then fed via the output-side connector 16 and a connectable to this in the usual way output line, for example, a signal receiver.

The filter part 12 has a sleeve-shaped housing 30, which is screwed on the one hand to the input-side contact sleeve 26 and on the other hand to the output-side contact sleeve 28. By means not shown in the drawing, per se known sealing elements, for example by means of sealing rings, a watertight connection between the filter part 12 and the input and output side connectors 14, 16 can be made.

The high-pass filter 10 is designed in a coaxial design, wherein the input and output side contact sleeves 26 and 28 in conjunction with the housing 30 form an outer conductor, which can be grounded, for example, and represents a ground line. The input and output side contact sleeves 26, 28 and the housing 30 receive a central inner conductor 32, which connects the input-side contact socket 22 with the output-side contact socket 24 and is electrically isolated from the contact sleeves 26, 28 and the housing 30. To ensure a distance between the inner conductor 32 and the contact sleeves 26, 28 and the housing 30, the inner conductor 32 in the adjoining the contact sockets 22 and 24 areas each by means of a support sleeve 34 and 36, which is made of an electrically insulating material, kept at a distance from the input-side contact sleeve 26 and the housing 30. Within the filter part 12 additional spacers in the form of spiral coils 38, 39, 40, 41 are used, which will be described in more detail below.

In FIG. 3 an electrical circuit diagram of the filter part 12 is shown. It can be seen that the inner conductor 32 connects the signal input 18 to the signal output 20, wherein in the inner conductor 32, a first and a second capacitance 43 and 44 and a third and a fourth capacitance 45 and 46 are connected in series and between the first capacitor 43 and the second capacitor 44, a first impedance 48, between the second capacitor 44 and the third capacitor 45, a second impedance 49 and between the third capacitor 45 and the fourth capacitor 46, a third impedance 50 is connected. In the region between the signal input 18 and the first capacitor 43 branches off from the inner conductor 32 from a first inductance 52, which is connected via a fifth capacitor 54 to the housing 30 of the filter member 12, wherein the housing 30, as already explained, the grounded outer conductor of the High pass filter 10 is formed. A second inductor 56 branches off in the region between the second capacitor 44 and the second impedance 49 from the inner conductor 32 and is connected via a sixth capacitor 57 to the outer conductor acting as a housing 30 in electrical connection.

In the region between the second impedance 49 and the third capacitance 45 branches off from the inner conductor 32 from a third inductance 49, which is also connected via a seventh capacitance 60 to the housing 30. A fourth inductor 62 branches off in the region between the fourth capacitor 46 and the signal output 20 from the inner conductor 32 and is connected via an eighth capacitor 63 to the grounded housing 30 in electrical connection.

The filter part 12 thus forms a first pi-member 65 and a second pi-member 66, which are connected to each other via the second impedance 49. The first pi-member 65 is controlled by the first and second inductors 52, 56 and the in Row to these switched fifth and sixth capacitances 54, 57 and from the first and second capacitances 43, 44 and the first impedance 48 connected between them. The second pi-gate 66 is constituted by the third and fourth inductors 59, 62 and the seventh and eighth capacitors 60, 63 connected in series therewith, and the third and fourth capacitors 45, 46 connected in series and the third connected between them Impedance 50 is formed.

The first to fourth capacitances 43, 44, 45, 46 are configured identically in electrical terms and also in mechanical terms - which will be discussed in greater detail below. They each have a value of a few pF. Also, the first to fourth inductors 52, 56, 59 and 62 are identical in both electrical and mechanical respects. They each have a value of a few nH.

If a high-frequency signal is applied to the signal input 18, it experiences a different attenuation as a function of its frequency. This is in FIG. 4 schematically illustrating the transmission loss between the signal input 18 and the signal output 20 in dependence on the frequency of the signal. It is clear that signals with a frequency of more than 1.4 GHz experience virtually no attenuation, whereas signals with a frequency of less than 1.4 GHz are subject to very high attenuation. Thus, for example, signals with frequencies in the range of 0.8 to 1.0 GHz can be practically masked out, whereas signals with frequencies in the range of 1.7 to 2.7 GHz, the high-pass filter 10 can pass unhindered.

The inductors 52, 56, 59 and 62 are formed by the spiral coils 38, 39, 40 and 41 already mentioned above with respect to their distance-maintaining function. These are designed identically and each form discrete electrical components, which are arranged at a distance to each other in order to avoid mutual electrical interference. The structure of the coils 38 to 41 is particularly made FIG. 2 clear. Starting from an inner sleeve 68 surrounding the inner conductor 32 in the circumferential direction, they extend spirally up to an outer sleeve 69, wherein they extend in a plane oriented perpendicular to the inner conductor 32. The outer sleeve 69 not only forms the outer contact of the spiral coils 38, 39, 40 and 41, but also simultaneously provides a first contact electrode of the capacitors 54, 57, 60 connected in series with the respective coils 38, 39, 40 and 41, respectively These capacitors are in each case configured as tube capacitors 71, 72, 73 and 74, the inner contact electrode of the tube capacitors 71, 72, 73, 74 being formed by the outer sleeve 69 and the outer contact electrode being formed by the housing 30. Between the outer sleeves 69 and the housing 60 extends a housing 30 lining the insulating layer 76, which thus represents the dielectric of the tube capacitors 71 to 74.

The inner sleeve 68 of the first coil 38 is penetrated by a rear end piece 78 of an input section 79 of the inner conductor 32 which faces away from the input-side contact socket 22 and electrically connects the input-side contact socket 22 to the inner sleeve 68 of the first coil 38. At the input portion 79, a first intermediate portion 81 of the inner conductor 32 connects with the interposition of a tube capacitor 83, which forms the first capacitor 43 and its structure explained in more detail below becomes. With the interposition of a further tube capacitor 84, which forms the second capacitor 44 and is configured identically to the tube capacitor 83, connects to the first intermediate portion 81, a connecting portion 86 of the inner conductor 32, and the connecting portion 86 is connected via a tube capacitor 87, which is the third Capacitance 45 is formed and identical as the tube capacitors 83 and 84 is formed, with a second intermediate portion 89 of the inner conductor 32 in electrical connection. The second intermediate section 89 is adjoined by an additional tubular capacitor 90, which forms the fourth capacitor 46 and has the same design as the tubular capacitors 83, 84 and 87, an output section 92 of the inner conductor 32. At the output section 32, the output-side contact socket 24 is connected.

The first intermediate portion 81 of the inner conductor 32 forms the first impedance 48 and is integrally connected to a front contact sleeve 94 and a rear contact sleeve 95 which receive a front insulating sleeve 97 and a rear insulating sleeve 98. In the front insulating sleeve 97, the rear end portion 78 of the input portion 79 dives, and in the rear insulating sleeve 98 dives a front end portion 100 of the connecting portion 86 a. The rear end portion 78 of the input portion 79, in combination with the front insulating sleeve 97 and the front contact sleeve 94, forms the tube capacitor 83, which constitutes the first capacitor 43.

The connecting portion 86 has a front end piece 100 facing the first intermediate portion 81 and a rear end piece 101 facing the second intermediate portion 89. The front end 100 dips into the rear insulating sleeve 98, which is surrounded by the rear contact sleeve 95 is. The front end 100 thus forms, in combination with the rear insulating sleeve 98 and the rear contact sleeve 95, the tube capacitor 84, which constitutes the second capacitor 44.

The second intermediate portion 89 is configured identically as the first intermediate portion 81 of the inner conductor 32. Also, the second intermediate portion 89 is integrally connected to a front contact sleeve 102 and a rear contact sleeve 103 which receive a front insulating sleeve 105 and a rear insulating sleeve 106. In the front insulating sleeve 105 dives the rear end portion 101 of the connecting portion 86, which thus forms in combination with the front insulating sleeve 105 and the front contact sleeve 102, the tube capacitor 87, which is the third capacitor 45. Inserted into the rear insulating sleeve 106 is a front end portion 108 of the output portion 92 which, in combination with the rear insulating sleeve 106 and the rear contact sleeve 103, forms the tube capacitor 90, which constitutes the fourth capacitor 46.

The first intermediate portion 81 forms the first impedance 48, the connecting portion 86 forms the second impedance 49, and the second intermediate portion 89 forms the third impedance 50. The high-pass filter 10 can thus be manufactured and assembled in a structurally simple manner, it being ensured that the inductors 52, 56, 59 and 62 in the form of spiral coils 38, 39, 40 and 41, which are formed as discrete electrical components, are spaced apart from one another between the coils 38, 39, 40, 41 in each case one of a line section of the inner conductor 32 formed impedance 48, 49 and 50 is arranged. The high-pass filter 10 can be formed in this way in a coaxial design, wherein signals be passed with a frequency greater than 1.4 GHz practically unattenuated from the signal input 18 to the signal output 20, whereas signals with a frequency less than 1.4 GHz are subject to a strong attenuation.

In FIG. 3 dash-dot is still a supplement of the circuit diagram shown according to a further advantageous embodiment of the high-pass filter by a node 110 is provided between the first inductor 52 and connected in series with this fifth capacitor 54, to which a terminal 111 can be connected to feed and / or picking up a supply or control voltage. In a corresponding manner, a node 113 is provided between the fourth inductor 62 and the eighth capacitor 63 connected in series with it, to which a terminal 114 can be connected, via which a supply or control voltage can also be fed or tapped. For example, a supply voltage can be connected or tapped at the terminals 111 and / or 114, which is supplied to an amplifier. In the same way, control signals, in particular signals for controlling an antenna, can be fed or tapped by means of the terminals 111 and 114. This is possible because it is ensured by means of each connected in series with an inductor 52, 56, 59, 62 capacitance 54, 57, 60 and 63 that no galvanic connection between the inner conductor 32 and the grounded housing 30, the Function of an external conductor takes over.

Claims (22)

High-pass filter comprising a signal line with a plurality of capacitors connected in series and a ground line, wherein a plurality of inductances are connected between the signal line and the ground line,
characterized in that the signal line forms an inner conductor (32) and the ground line forms an outer conductor (30) of a coaxial conductor, between which an insulating layer (76) is arranged, and in that the inductors (52, 56, 59, 62) are spaced apart arranged discrete components (38, 39, 40, 41) are configured, between which at least one impedance (48, 49, 50) is connected. High-pass filter according to claim 1, characterized in that at least one inductance (52, 56, 59, 62) as a spiral-shaped coil (38, 39, 40, 41) is configured. High-pass filter according to claim 1 or 2, characterized in that the inductors (52, 56, 59, 62) are configured electrically and / or mechanically identical. High-pass filter according to claim 1, 2 or 3, characterized in that the at least one impedance (48, 49, 50) as a line section (81, 86, 89) of the inner conductor (32) is configured. High-pass filter according to one of the preceding claims, characterized in that in the inner conductor (32) connected in series with each other capacitances (43, 44, 45, 46) are configured identical in terms of their electrical and / or mechanical properties. High-pass filter according to one of the preceding claims, characterized in that in the inner conductor (32) connected in series with each other capacitances (43, 44, 45, 46) as plate or tube capacitors (83, 84, 87, 90) are configured. High-pass filter according to one of the preceding claims, characterized in that the high-pass filter (10) comprises at least one pi-member (65, 66) with a pair of inductors (52, 56; 59, 62) connected between the inner conductors (32) and the outer conductor (30) are connected, wherein between the two inductances (52, 56; 59, 62) in the inner conductor (32) a first capacitance (43; 45), an impedance (48; 50) and a second capacitance (44 ; 46) are connected in series with each other. High-pass filter according to claim 7, characterized in that the two capacitances (43, 44, 45, 46) are configured identically in terms of their electrical and / or mechanical properties. High-pass filter according to claim 7 or 8, characterized in that the two capacitors (43, 44, 45, 46) are designed as plate or tube capacitors (83, 84, 87, 90). High-pass filter according to Claim 7, 8 or 9, characterized in that the impedance (48; 50) connected between the two capacitors (43, 44; 45, 46) is designed as a line section (81; 89) of the inner conductor (32). A high-pass filter according to claim 10, characterized in that the line section (81; 89) carries front and rear electrically conductive contact sleeves (94, 95, 102, 103) each receiving a dielectric insulating sleeve (97, 98, 105, 106) into which an end piece (78, 100, 101, 108) of a further line section (79, 86, 86, 92) of the inner conductor (32) is inserted. High-pass filter according to claim 11, characterized in that the front and rear contact sleeves (94, 95; 102, 103) are integrally connected to the line section (81; 89) interconnecting the two capacitors (43, 44; 45, 46). High-pass filter according to one of claims 7 to 12, characterized in that the high-pass filter (10) has two pi-members (65, 66) which are connected to one another via an impedance (49). High-pass filter according to claim 13, characterized in that the impedance (49) is designed as a line section (86) of the inner conductor (32). High-pass filter according to claim 13 or 14, characterized in that the two Pi-members (65, 66) are configured identically in terms of their electrical and / or mechanical properties. High-pass filter according to one of the preceding claims, characterized in that between at least one inductance (52, 56, 59, 62) and the outer conductor (30) has a capacitance (54, 57, 60, 63) connected in series. High-pass filter according to Claim 16, characterized in that a connection (111, 114) for feeding and / or picking up a supply or control voltage is arranged between at least one inductor (52; 62) and the capacitor (54; 63) connected in series therewith is. High-pass filter according to one of the preceding claims, characterized in that it can be inserted in a coaxial transmission line. High-pass filter according to one of the preceding claims, characterized in that the outer conductor forms a rigid housing part (30) of the high-pass filter (10). High-pass filter according to claim 19, characterized in that the insulating layer (76) the housing part (30) on the inside at least partially lined. High-pass filter according to claim 20, characterized in that the insulating layer (76) forms a dielectric of at least one capacitance (54, 57, 60, 63) which is connected in series with an inductor (52, 56, 59, 62). High-pass filter according to one of the preceding claims, characterized in that at least one inductance (52, 56, 59, 62) forms a mechanical spacer between the inner conductor (32) and the outer conductor (30).

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