SE523244C2 - Converter - Google Patents

Description

25 30 35 »a o a. aoo 0 0 00 523 244 "2 to another. Microwaves in TE mode propagate in a well-defined manner and without being distorted in a correctly dimensioned, so-called waveguide channel. In addition, the microwaves in TE mode pass through such a channel substantially losslessly A waveguide channel can also be produced cost-effectively by milling a groove in a metal block, however, TEM mode microwaves cannot propagate in such a waveguide channel.

The TEM mode is preferred in applications where the bandwidth extends over several octaves, for example when filtering.

TEM mode microwaves are usually routed in a coaxial cable. It is also possible to conduct microwaves in TEM mode in a waveguide channel with a copper foil, the microwaves propagating between the foil edge and the channel walls. TEM-mode microwaves cannot be conducted in a controlled and well-defined manner in any of these TEM-mode microwave conductors.

In order to be able to connect applications for microwaves in TE mode with applications for microwaves in TEM mode, it is necessary to use a transition for converting microwaves from either modern TE mode and TEM mode to the other mode. In such transitions, it is a problem that microwaves are very sensitive to dimensional changes and other disturbances in the conductor.

When a microwave is disturbed by a dimensional change, it does not move forward but is reflected back. Therefore, for example, it is not possible to directly connect a waveguide channel for microwaves in TE mode with a waveguide channel with copper foil for microwaves in TEM mode. Dimensional changes in the duct usually have to take place gradually and over long distances, which is why corresponding components are forced to become undesirably large.

A known transition is a so-called coaxial waveguide transition. In such a case, the waveguide channel ends with a solid wall. A carefully calculated piece from this wall is the inner conductor of a coaxial cable inserted into the channel through uno nu 10 15 20 25 30 35 523 244, u n n o | u n a n n co uno 3 a circular hole in one of the walls of the waveguide channel.

The outer sheath of the coaxial cable is connected to the wall of the waveguide channel around this hole.

Another known transition is a so-called loop-connected coaxial waveguide transition. Even with one, the waveguide channel ends with a solid wall. The inner conductor of a coaxial cable is inserted into the waveguide channel through a circular hole in the solid wall. The inner conductor is bent inside a channel in a loop and its end is connected to the wall. The outer sheath of the coaxial cable is connected to the solid wall around the hole.

Thus, a prior art microwave component, in which microwaves are processed in both TE mode and TEM mode, usually includes a waveguide channel milled in a metal block for TE mode microwaves and some application for TEM mode microwaves. Between these, one of the said transitions with a solid wall in the waveguide channel and a coaxial cable is placed.

A disadvantage of these known transitions is that they constitute complex solutions with several components. Therefore, it is a problem that the final product becomes correspondingly awkward with both blocks for the waveguide channel and partly a separate detail for the TEM application and coaxial cables between them. It is also a problem that the assembly is cumbersome and expensive. These problems become particularly noticeable in the manufacture of microwave components in large series.

Summary of the invention In view of the above, it is an object of the invention to provide a transition where microwaves are converted from either of modern TE modes and TEM modes to the other mode, which transition is compact and technically simple.

This object is achieved according to the invention by means of a TE / TEM converter which comprises a transition section with a TE port for passage of microwaves in TE mode and a TEM 10 15 20 25 30 35 n as c n nn a p n. .N | n n v n nu -_- n; v f, - .- s n -.- 1 un: un; i .. u. o I Ill I 'O o. n o; e n ø | u n u n a. There are now 4 ports for passing microwaves in TEM mode, the Transition Section being arranged to cause at least substantially an entire microwave arriving via either port to pass through the Transition Section during conversion of the microwave from either of said TE and TEM modes to the other. mature. The TE / TEM converter according to the invention is characterized in that the Transition Section is arranged to generate by said incoming microwave, during its passage through the Transition Section, several reflection waves which take each other out.

The TE / TEM converter according to the invention is thus intended for converting electromagnetic waves from either of modern TE modes and TEM modes to the other mode. By microwaves is generally meant electromagnetic waves in the frequency range 300 MHz to êßfê fi z.

The TE / TEM converter according to the invention is primarily intended for frequencies up to 100 GHz. The converter has no physical downward limitation, but for practical reasons waveguides above about 1 GHz are normally used, however, it is conceivable with waveguides all the way down to 300 MHz, including in particle accelerators.

The TE / TEM converter according to the invention comprises a transition section provided with ports. The term "gate" refers to a detail through which something can pass and which can otherwise be designed in different ways. It is thus possible, for example, for a gate to have a certain extent, but it can also be considered to have infinite small dimensions in the direction of passage. The transition section according to the invention comprises a gate through which microwaves in TE mode can pass and a gate through which microwaves in TEM mode can pass. An incoming microwave in TE mode can enter the transition section only through the TE port and an incoming microwave in TEM mode can enter the Transition section only through the TEM port. Correspondingly, a microwave in TE mode can only leave the transition section through the TE port vv: vn nu »n 10 15 20 25 30 35; ø | n a ø o u o ø oo n 1 o un; ø ø ø: u o nu ana 523 244 5 as well as a microway in TEM mode can only leave the transition section through the TEM port. The transition section is designed in such a way that a microwave that has entered through one of the gates essentially completely passes out through the other of the gates. The transition section thereby affects the microwave in such a way that it changes mode during its passage through the transition section. A microwave in TE mode that passes in through the TE port thus passes out through the TEM port in TEM mode and vice versa. In this case, essentially none of the energy of the microwave is lost. The transition section is further designed so as to provide several reflection waves of a microway that has passed into the transition section. These reflection waves then relate to each other so that they take each other out, ie the sum of all reflection paths is zero.

According to the energy conservation principle, all energy is conserved, which is why the microwave is forced into and through the transition section. In doing so, it must also change mode to be able to pass out through the other gate.

The basis of the invention is thus an insight that the often undesired reflection waves, which often occur in connection with microwaves, can be used positively.

Contrary to known technology for TE / TEM converters, the reflection waves are a prerequisite for the microwave to spread further and for the invention to work.

Due to the fact that reflection waves according to the invention are not undesirable but on the contrary necessary, dimensional changes over relatively short distances are possible.

Thus, according to the invention, it is possible to provide a compact TE / TEM converter.

With the aid of the TE / TEM converter according to the invention, an application for microwaves in TE mode and an application for microwaves in TEM mode can thus be interconnected, the TE / TEM converter constituting a compact and technically simple component. van oo 10- 15 20 25 30 35 I o ø a Q ø o. a u o: o 523 244 o | o n; According to an embodiment of the invention, the transition section is arranged so that first and second reflection waves are formed in parallel, the first and the second reflection waves taking each other out. Such a design is advantageous because it enables the TE / TEM converter according to the invention to be used for microwaves within a larger frequency range. If the transition section is arranged to form the first and the second reflection waves one after the other, i.e. in series, it can only function for wavelengths within a limited range. For wavelengths outside this range, it is not possible to produce reflection waves which are in opposite phase in such a way that they cancel each other out. By means of a transition section which, on the other hand, forms the first and the second reflection waves in parallel, the interval for possible wavelengths becomes larger.

According to another embodiment of the invention, the TE / TEM converter can be realized in such a way that the transition section comprises a transition channel and a transition foil which is arranged with at least one portion in the transition channel. The transition channel and the transition foil each comprise at least one dimensional change. An incoming microwave which has passed into the transition through one of the ports is thereby reflected partly towards the dimensional change of the transition foil as first reflection waves and partly towards the dimensional change of the transition channel as second reflection waves. The dimensional changes of the transition channel and the transition foil are so adapted to each other that said generated first and second reflection waves cancel each other out.

Furthermore, the foil and the portions of the transition channel that an incoming microwave is reflected against are arranged substantially parallel, so that the first and the second reflection waves are formed in parallel.

In this case, a resulting first reflection wave is the sum of all the first reflection waves and a resulting second reflection wave is the sum of all other reflection waves. The resulting first reflection wave has the same amplitude and frequency as the resulting second reflection wave, but oscillates in opposite phase.

Microwave components which, such as in E-plane technology, include a channel and a foil are easy to manufacture provided that the necessary tolerances are met. The channel can be milled in a metal block and the foil can be punched or wire sparked out of large foil sheets.

According to another embodiment, the transition channel extends from the TE gate to the TEM gate and has a larger cross section at the TE gate than at the TEM gate.

Applications for microwaves in TEM mode usually have a channel with a smaller cross section than a waveguide channel for microwaves in TE mode. The transition channel thus shows a dimensional change, for example in the form of a stepwise or a continuous reduction of the cross section, between the TE gate and the TEM gate. The transition section also has an E-plane. The transition foil is advantageously placed in the middle of the transition channel, the plane of the transition foil coinciding with the E-plane of the transition section. The active portion of the transition foil is thus in the transition channel. The transition foil has a length in the longitudinal direction of the transition channel, a height across the channel in the E-plane and a thickness across the channel perpendicular to the E-plane. According to a preferred embodiment, the height of the transition foil is smaller at the TE gate than at the TEM gate. The transition foil thus shows a dimensional change, for example in the form of a stepwise or a continuous increase in height, between the TE port and the TEM port. In this case, the transition foil does not cover the entire channel, but at least a portion of one of the longitudinal edges of the transition foil is located in the transition channel without contact with the channel walls of the transition channel. Such a design of .. -oqn 10 15 20 25 30 35 u n than a v u n 'n v n n u. n n v u oo n n n o ~. u o v a nu »nu nu 2. a a n 4 n n n n o; With a suitable design of the transition foil and the transition channel, the first and second reflection waves thereby cancel each other out.

According to the invention, it is possible to design the TE / TEM converter in two converter block halves. A first half of the transition channel can then be milled in one converter block half and a second half of the transition channel in the other converter block half. The first and second converter block halves are complementary. They are joined so that the two transition channel halves end up opposite each other and together form the transition channel. The transition foil is manufactured separately and can, for example, be punched out of a large sheet of foil or sparked wire. The transition foil is arranged between the block halves with at least one portion in the transition channel.

With this preferred design of the TE / TEM converter according to the invention, the assembly becomes particularly simple. Furthermore, the TE / TEM converter can easily be built in or connected to other microwave components in E-plane technology. They then form essentially flat, two-dimensional structures that are compact and easy to assemble.

According to the invention, the dimensional changes in the transition channel and the transition foil necessary to achieve the first and second reflection waves can be realized in many different ways. Thus, the transition channel usually has a rectangular cross section and four edge walls. One or more of these edge walls may be provided with one or more steps. It is also possible that one or more of the edge walls are provided with a tapering. Likewise uno about 10 15 20 25 30 35 V j I pg; I I Il IIOI Il CIO! O I, v - ~ u: v v n n q .o cr I “o v; u v e u n a I i !!! n, n »i., n 4 .. I u. 1 i v n u a u I I I I I II II 'CI 9 you can combine tapering with steps in one or more of the duct walls.

By "steps" is meant here a stepwise change of the cross-section of the transition channel. A duct wall provided with a step has a portion which is offset towards the center of the duct. The change in the cross section of the channel can take place through one or more steps.

By "tapering" is meant a continuous change of the cross section of the channel. A channel wall which is provided with a tapering has a ramp-shaped portion sloping in the longitudinal direction of the channel towards the center of the channel. The transition foil can also be designed with one or more steps. It then has a stepped edge in the channel.

It is also possible to design the transition foil with a tapering. Then the transition foil has a continuously ramp-shaped edge sloping towards the center of the channel.

It is also possible to combine tapering with steps in the transition channel and the transition foil.

It is also possible to design the transition foil in two parts which are arranged between the block halves on each side of the transition channel. In this case, at least one half extends into the transition channel. One half can serve as a distance and have no party at all in the transition channel.

Of course, the existing transition channel and transition foil must always be adapted to each other, so that emerging reflection waves cancel each other out.

With such a dimensional change of the channel and the foil, an impedance transform is obtained. A transformation in one step can be achieved, for example, by a dimensional change of two opposing channel walls in the form of two steps in each channel wall and a foil adapted to the dimensional change in question, for example with a tapering.

The TE / TEM converter will be described in more detail in the following description of preferred embodiments. . -. The present invention also makes it possible to produce technically simple, compact microwave components, which include portions for microwaves in TE mode and portions for microwaves in TEM mode. and TE / TEM transitions between them.

A general example of such a microwave component is a converter device comprising a first and a second TE / TEM converter according to claim 1. The converter device further comprises a TEM section for microwaves in TEM mode with a first and a second TEM port for passage of microwaves in TEM mode, the first TE / TEM converter being connected to the first TEM port of the TEM section with its transition section TEM port and the second TE / TEM converter being connected to the second TEM section of the TEM section port with its transition section TEM port.

The converter device according to the invention thus has a TEM section for microwaves in TEM mode. This TEM section has two TEM ports through which microwaves in TEM mode can pass.

The first and second TE / TEM converters each include their own transition section. Each transition section has a TE gate through which microwaves in TE mode can pass and a TEM gate through which microwaves in TEM mode can pass.

The first TE / TEM converter is connected to the first TEM port of the TEM section with its TEM port and the second TE / TEM converter is connected to the second TEM port of the TEM section with its TEM port.

The TE ports of the first and second TE / TEM converters can either themselves constitute the external ports of the converter device or be connected to the external ports of the converter device. The outer ports can then in turn be connected to a TE-mode microwave environment or to other TE-mode microwave components.

In this way, the converter device can be easily placed in a structure for microwaves in TE mode. ~ s ..-.-- v ~ v ~ _ - '- - v .. unge v »- v -_ s -» - ~. us I - uvu- - veu - vw u '.- uv 10 15 20 25 30 35 vnoo oc s2a 244 g; §; ¿; 3 @: ~, ll Microwaves in TE mode pass into the converter device through one of the TE the ports after which those of the TE / TEM converter are converted to TEM mode and pass into the TEM section through one of its TEM ports. There, the microwaves are processed in the manner in question, after which they pass into the second TE / TEM converter through the second of the TEM sections of the TEM section. There, the microwave food is converted to TE mode and passes out of the converter device through the second TE port.

According to one embodiment, the first and second TE / TEM converters are equal and mirror-inverted. This provides constructive benefits.

According to another embodiment, the first and second TE / TEM converters are not the same, but adapted and optimized to the applications to which they are connected.

According to a further embodiment of the converter device, the first TE / TEM device and the second TE / TEM device and the TEM section are integrated. Thus, several of the constituent parts can be manufactured in one piece. The transducer device can also be designed with two complementary device block halves with an intermediate device foil.

The TEM section of the transducer device can be designed in many different ways to achieve the desired treatment of the microwaves. Examples of TEM sections are low-pass waveguide filters, attenuators, switches and amplifiers.

In the example of a low-pass waveguide filter such as the TEM section, the low-pass filter thus works for microwaves in TEM mode.

The low-pass filter comprises in one embodiment a low-pass waveguide filter channel and a low-pass filter foil which is arranged with at least one portion in the low-pass waveguide filter channel.

The low-pass waveguide filter channel can be milled in block halves. The low-pass waveguide filter foil may be provided with TEM resonators. 10 15 20 25 30 35 | u o u - n ø o I I II. 523 244 ïÛfw * š, u. | o n a u .u n. 12 In an integrated embodiment, the block halves of the low-pass filter form a portion of the device block halves, just as the low-pass waveguide filter channel forms a portion of the device channel and the low-pass waveguide filter foil forms a portion of the device foil.

The converter device and the low-pass filter will be explained in more detail in the following description of preferred embodiments.

An example of a microwave component which advantageously comprises a low-pass waveguide filter and a TE / TEM converter according to the invention is a diplexer. A known diplexer is described in the Swedish patent application SE 0002521-3. Such diplexers are used, for example, in base stations in mobile telephony.

Sometimes it may be necessary to filter out signals with high frequencies, such as so-called harmonics. This may, for example, be necessary for the protection of the equipment to which the diplexer is connected. In connection with mobile telephony, it is also a government requirement not to emit harmonics.

There are known low-pass waveguide filters for microwaves in TE mode, such as a low-pass waveguide filter which is milled in a waveguide channel and has a plurality of projecting fingers with narrow passages between them. Such a filter is time consuming to manufacture and requires very tight tolerances. In addition, such a filter transmits signals, or microwaves, which have certain frequencies even though these are within the range that the filter should filter out.

Low-pass waveguide filters that work with resonators in TEM mode have better harmonic attenuation properties than resonators that work in TE mode.

Until now, it has not been possible to design better-functioning and technically simpler low-pass guide filters for microwaves in TEM mode in a diplexer, as known transitions between TE mode and TEM mode have been too clumsy and time-consuming to install. 10 15 20 25 30 35 n ~ u u - I o ø | | With a TE / TEM converter according to the invention, however, it is now possible to provide a diplexer with a simple mechanical design which has a low-pass waveguide filter which is intended for filtering microwaves in TEM mode, for example a combline filter. Since the diplexer is otherwise intended for microwaves in TE mode, at least one TE / TEM converter according to the invention is also required.

A diplexer according to the invention thus comprises at least one converter device, which comprises a low-pass waveguide filter for filtering microwaves in TEM mode and a first and a second TE / TEM converter according to the invention.

The diplexer according to the invention is provided with at least one converter device. It is possible to provide the diplexer with several converter devices, for example at both antenna and transmitter if, for example, filtering in one step is not sufficient. According to an embodiment of the invention, the diplexer is provided with a converter device at the antenna as well as the transmitter and the receiver.

According to an embodiment of the invention, the diplexer is of a type which comprises a filtering section which preferably has a portion which functions as a receiver filter and a portion which functions as a transmitter filter. The filtration section comprises a filtration channel and a filtration foil arranged with at least one portion in the filtration channel and its plane in the E-plane.

The filter foil can be wire sparked from a larger sheet of foil and is provided with sparked poles.

A diplexer which is designed in this way is technically simple, which means that a similarly technical TE / TEM converter according to the invention does not unnecessarily complicate and make production more expensive. When mounted in base stations, it is an advantage that the diplexer is compact, which is made possible by the compact TE / TEM converter according to the invention. nß-uu 10 15 20 25 30 35 523 244 »n ø o u. According to one embodiment of the diplexer, a transducer device is arranged between the filtering section and the antenna, another transducer device is arranged between the filtering section and the transmitter and still another transducer device between the filtering section and the receiver, the transducer devices having ports allowing them to be connected to respective portions.

In the converter devices, TE / TEM converters are connected to a low-pass waveguide filter in the same way as described above in connection with the converter device.

According to the invention, the converter devices can be provided with only one TE / TEM converter if they are to be connected within the diplexers to a section which is intended for microwaves in TEM mode.

The converter device can otherwise be identical to a converter device according to the invention in which the TEM section consists of a low-pass waveguide filter.

According to one embodiment of the diplexer, the filtration section and the transducer devices are integrated with each other. Thus, several of the constituent parts can be manufactured in one piece.

Thus, the diplexer can also be designed with two complementary diplexer block halves with an intermediate diplexer foil.

The diplexer will be explained in more detail in the following description of preferred embodiments.

Brief Description of the Drawings The invention will be described in more detail below by means of exemplary embodiments with reference to the accompanying drawings.

Fig. 1 shows a first embodiment of a TE / TEM converter according to the invention with steps in a section through the common plane between the converter block halves of the TE / TEM converter without transition foil. ;.;. n 10 15 20 25 30 35. ; Fig. 2 shows in a view perpendicular to that of Fig. 1 a central, longitudinal section through the first embodiment of the TE / TEM converter.

Fig. 3 shows in a view perpendicular to those in Figs. 1 and 2 a central, transverse section through the first embodiment of the TE / TEM converter.

Fig. 4 shows a first embodiment of a transition foil with a tapering portion and a spacer foil.

Fig. 5 shows a second embodiment of a transition foil with steps and a spacer foil.

Fig. 6 shows a third embodiment of a TE / TEM converter according to the invention with a tapering portion in a section through the common plane between the converter block halves of the TE / TEM converter without transition foil.

Fig. 7 shows in a view perpendicular to that of Fig. 6 a central, longitudinal section through the third embodiment of the TE / TEM converter.

Fig. 8 shows a first embodiment of a transducer device according to the invention with a low-pass waveguide filter in a section through the common plane between the transducer block halves of the transducer device without device foil.

Fig. 9 shows in a view perpendicular to that of Fig. 8 a central, longitudinal section through the first embodiment of the converter device.

Fig. 10 shows in a view perpendicular to those of Figs. 8 and 9 a central, transverse section through the first embodiment of the converter device.

Fig. 11 shows a first embodiment of a device foil in two parts.

Fig. 12 shows a second embodiment of a device foil with different designs for the respective TE / TEM converters.

Fig. 13 shows in a device foil with a resistive film for a transducer device with a damper. a, | eø 10 15 20 25 30 35 523 244 .a. | a Q n ~ fl ".. v. 1 ~" 'n 16 Fig. 14 shows a transducer device with a switch in two different views and an associated device foil.

Fig. 15 shows a first embodiment of a diplexer and a diplexer foil.

Description of preferred embodiments Figures 1-3 show in cross section a first embodiment of the TE / TEM converter 6 according to the invention and Fig. 4 shows a first embodiment of a transition foil 20 and a spacer foil 21 intended for such a TE / TEM converter 6.

This first embodiment is primarily intended for microwaves with frequencies in the range of 10 to 40 GHz. However, it also works for microwaves with other frequencies, at least up to 100 GHz.

The TE / TEM converter 6 comprises a converter block 1 with a guide conductor channel 2. The converter block 1 comprises a first converter block half 3 and a second, with the first converter block half 3 complementary converter block half 4. In each block half 3, 4 a half of the guide conductor channel 2 is milled. When the transducer block halves 3, 4 are joined, the waveguide channel halves are opposite each other and form the waveguide channel 2. The dividing plane 5 of the transducer block halves constitutes the E-plane of the TE / TEM transducer.

The TE / TEM converter 6 according to the invention comprises a transition section 7 with a transition channel 8. The transition channel has a TE port 9 for passage of microwaves in TE mode and a TEM port 10 for passage of microwaves in TEM mode. The transition channel 8 has a rectangular cross section with a height bi the dividing plane 5 and a width a perpendicular to the dividing plane 5. The transition channel further has four channel walls 14, 15, 16, 17. The transition channel extends from the TE gate to the TEM gate 10 and its length is about X Ä, maximum about one wavelength. However, it is possible to make the transition channel 8 even shorter, but it must be at least approximately% Ä long. Different parts of the transition channel: see ID via-n 10 15 20 25 30 35 ø | n | u: v i 523 244 v,. oc: 17 has different dimensions. More specifically, in this embodiment, the cross section is larger at the TE gate 9 than at the TEM gate 10.

According to the first embodiment of the TE / TEM converter 6, the transition channel 8 is provided with a dimensional change in the form of steps 11, cf. Fig. 2. In the exemplary embodiment, the width a of the transition channel 8 is reduced in two steps by means of the steps 11. The steps 11 are formed in each of two opposite channel walls 14, 16 in the transition channel 8. Furthermore, the steps 11 are symmetrical over the division plane 5 of the transducer block 1, so here only the steps 11 in one channel wall 16 are described. The first step 11 is located approximately% Ä from the TE gate and the second step approximately% Ä after the first step 11.

In this case, a plane step 13 is formed which extends over% Ä.

The first step 11 reduces the width of the channel to approximately 80% of the original width. The second step ll has smaller cross-sectional dimensions than half a free wavelength for the highest frequency for which the converter is to be used.

Fig. 1 shows that the cross section of the transition channel 8 decreases from the TE gate 9 to the TEM gate 10 also in height b. The reduction takes place in a rounded step 19 approximately in the middle of the transition section.

The step 19 is made in only one wall and the wall 19 opposite the step extends unaffected through the entire transition section.

Furthermore, the converter block half is provided with guide pins 28 and screws 12 for precise mounting of the TE / TEM converter 6.

The converter block halves 3, aluminum, but also other metals, plastics or 4 are made of material is possible. If the material is anything other than metal, they must be coated with a conductive surface.

For the invention, it is necessary to have at least two steps 11. It is thus also possible to provide 244 n 25 24 35 35 35 n ø n o on iszs 244. .- nu nu ::. : ',, | o ~,,. .- 18 the transition channel 8 with several steps 11.

From a manufacturing point of view, however, it is currently not attractive to have more than five steps 11.

Likewise, the steps 11 can alternatively be made in only one of the duct walls 14, 15, 16, 17 or in three of 15, 16, 17 or in all four duct walls 14, 15, 16, 17. The cross-section of the transition duct 8 at the TE gate and TEM the port can be connected to subsequent channels, the channel walls 14. In this case, however, for microwaves in TE mode and TEM mode, respectively.

The steps 11 do not have to be symmetrically arranged over the dividing plane 5.

The steps 11 can, but do not have to, have different heights.

Fig. 4 shows a first embodiment of a transition foil 20 according to the invention. The transition foil 20 is dimensioned to fit between the transducer block halves 3, 4. The transition foil 20 can be placed in recesses in the transducer blocks 3, 4 which correspond to the thickness and contour of the transition foil 20.

Further, the transition foil 20 has a first short side 25 located at the TE port when the transition foil 20 is located between the transducer block halves 3, 4 and a second short side 26 located at the TEM port when the transition foil 20 is located between the transducer block halves 3, 4. The transition foil 20 comprises, like the transition channel 8, a dimensional change, the dimensional changes of the transition channel 8 and the transition foil 20 being adapted to each other, which will be described in more detail below. The dimensional change of the transition foil 20 in this embodiment consists of a tapered portion 24. At the TE gate 9, the transition foil 20 has a height B which is maintained up to the transition channel 8.

From the TE gate 9 towards the TEM gate 10, the height B of the transition foil 20 increases continuously. Thus, the transition foil 20 obtains a longitudinal edge 27 having an inclined portion. When the transition foil 20 is placed between the transducer block halves 3, 4, it extends to, but not into, the transition channel 8 at the TE gate 9. Between the TE gate. 9 and the TEM port 10, on the other hand, a portion of the transition foil 20 will be located in the transition channel 8.

However, not even at the TEM port 9 does the transition foil 20 have such a height B that it reaches across the entire transition channel 8, but a small gap 30 remains free of foil.

The tapering portion 24 extends in the longitudinal direction of the transition channel 8 approximately% Ä. Longer distances are possible, but the smallest possible length is approximately% Ä. nor is it possible for a microwave to spread further.

Fig. 4 also shows a spacer foil 21. This is intended to prevent the transducer block halves 3, 4 from slipping when they are joined to the transition foil 20 between them. The spacer foil 21 is dimensioned so that it extends to but not into the transition channel 8 when the TE / TEM converter 6 is mounted. It thus has a long side 18 which follows one edge of the transition channel 8.

Both the transition foil 20 and the spacer foil 21 are provided with guide pin recesses 29 and screw holes 22 for the exact mounting of the TE / TEM converter 6. The transition foil 20 is made of copper, but other metals are also possible. It can be coated with precious metal or surface treated in another way to protect against corrosion.

However, the spacer film 21 is not necessary for the invention, but for some applications a small gap may be acceptable. It is also possible that one or both transducer block halves 3, 4 are slightly thicker on the opposite side of the transition foil 20 of the transition channel 8. The transition foil 20 can also extend all the way to the edges of the metal block.

In a variant of the first embodiment of the TE / TEM converter according to the invention it is also possible a: nu 00 æ.- ». 10 15 20 25 30 35. . ,,,,. , | | oo, n a u y I O !! O I gg I .Ü '..... .. - - zzn. .. ".. v. | ~. u: 3 ,,, 1- - vup .n n. =. z ._ i,.,, nn ß 'ß z' fn .- H 'H" f 20 att design the transition foil 20 and the spacer foil 21 symmetrically over the pitch 5 of the transition channel (not shown). In this variant, both the transition foil 20 and the spacer foil 21 are provided with a tapering portion which extends into the transition channel from each direction.

However, the portions do not reach all the way to each other, but a small gap in the transition channel 8 also remains free of foil in this embodiment. In this case, the spacer foil constitutes a second transition foil.

The first embodiment of the TE / TEM converter 6 according to the invention can be mounted in the following manner. First, guide pins 28 are placed in guide pin recesses 29 (not shown) in the first transducer block half 3. Thereafter, the transition foil 20 is threaded over the guide pins 28, its tapered portion being located in the transition channel 8. Thereafter, the spacer foil 21 is placed on the other side of the transition channel. for the second converter block half 4.

Then the second, complementary transducer block half 4 is threaded over the guide pins and placed against the foils 20, 21 on top of the first transducer block half 3. Finally, the transducer block halves 3, 4 are connected to each other by means of screws 12.

With this design of the TE / TEM converter according to the invention, the assembly thus becomes very simple.

Thus, in the composite TE / TEM converter 6, the transition foil 20 and the spacer foil 21 are located in the E-plane. Thus, the height B of the transition foil has the same orientation as the height b of the channel. The dimensional change of the transition foil 8, i.e. the tapered portion 24, takes place in the height B of the transition foil 8,

In a further variant of the first embodiment of the TE / TEM converter 6, however, the steps 11, as well as the tapering in the transition foil 8, are oriented in the same direction, either height or width. o. -vnpn l0 15 20 25 30 35 c o: Q no 1523 244 u o o n u n v I n o. n p: 21 However, in all embodiments, the transition foil must be placed with its plane in the E-plane.

In the first embodiment, the first step 11 of the transition channel 8 is located closer to the TEM gate than the point where the tapered portion 24 of the transition foil 20 extends into the transition channel 8. first and second reflection waves are generated in parallel by the tapering portion 24 in the transition foil 20 and the steps 11 in the transition channel 8 by a microwave arriving at the TE / TEM converter.

In a second embodiment of the TE / TEM converter according to the invention, the transition foil 20 is provided with a dimensional change in the form of step 31, cf. Fig. 5.

This transition foil 20 is intended to be placed in the same way between converter block halves 3, 4 of the same type and with a similar transition channel 8 as described in connection with the first embodiment of the TE / TEM converter according to the invention. The second embodiment of the TE / TEM converter according to the invention also comprises a spacer foil 21 which is identical to that described above.

By means of the step step 31, the height B of the transition foil 20 changes in a step which is approximately 1/8 Å high.

The height of the step 31 can, of course, vary.

For example, the height of the step 31 can be as low as 0.05 Ä and as high as 1/2 Ä. On both sides of the step 31, the height B of the transition foil is constant. In the mounted TE / TEM converter 6, the transition foil 20 and the spacer foil 21 are thus located between the converter block halves 3, 4. At the TE gate, on the first side of the step 31, the transition foil 20 extends to, but not into, the transition channel 8. On the other side of the step 31, a portion of the transition foil 20 is located in the transition channel 8. However, the transition foil 20 does not reach the uu 10 15 20 25 30 35 .nu n,. nu II '"' 5 3 l t. '..: kz y. z 2. -. zu' n. o» vf ¥ I:.,,, u. .va,.. u -s 0 '1. u: 22 across the entire transition channel 8 without a small gap 30 remains free of foil.The transition foil has its greater height in the longitudinal direction of the transition channel 8 over a distance of approximately M Ä. The smallest possible length is approximately% Ä.

In a variant of the second embodiment of the TE / TEM converter, the transition foil 20 is provided with several steps 31 (not shown), but for manufacturing reasons no more than five. They may be evenly distributed or extend differently along the transition channel 8, the total length being between% Ä and X Ä. They may have the same or different step heights, the total height being between 1/20 Ä and M Ä.

A third embodiment of the transducer block halves 3, 4 is shown in Figs. 6 and 7. These transducer block halves 3, 4 are intended to cooperate with a transition foil 20 which is of the same type as that described in connection with the second embodiment of the TE / TEM transducer. according to the invention, cf. Fig. 5. Except for the differences described in the following, the TE / TEM converter according to the third embodiment operates in the same way as those described above.

In the third embodiment of the TE / TEM converter 6 according to the invention, the transition channel 8 is provided with a dimensional change in the form of a taper portion 32, cf. Fig. 7. The width of the transition channel a is continuously reduced in the taper portion 32. The taper portion 32 is realized as a wedge-shaped ramp of two, opposite channel walls 14, 16 in the transition channel 8. Furthermore, the tapering portion 32 is symmetrical over the division plane 5 of the transition channel 5. The ramp starts approximately M constant width a. The height of the ramp depends on which a-dimension is desired for the transition channel 8 at the TEM gate 10. However, it is not possible to design the ramp 33 with a slope greater than about 80 degrees because it is then not possible to sow - _ < . v v ... uu-u av 'u u oc vn 10 15 20 25 30 35 523 244 23 adapt the reflection waves so that they touch each other, which is why it is also not possible for a microwave to propagate further.

In a variant of this third embodiment, the ramps in the tapered portion 32 are not symmetrical. It is also possible with variants where only one ramp is formed in one of the channel walls, just as it is also possible with ramps 33 in three or four channel walls.

Seen from the TE port 9 in the composite TE / TEM converter, the dimensional change of the transition foil 20 begins before the dimensional change in the transition channel 8. This applies to all embodiments of the TE / TEM converter according to the invention. Over a distance in the transition channel, the dimensional change of the transition foil 20 is arranged in parallel with the dimensional change in the transition channel 8, so that first and second reflection waves can be generated in parallel.

In all embodiments, it is very important that the dimensions of the transition channel 8 and the transition foil 20 are carefully matched to each other as well as to the application and frequency range of the microwaves in question. The TE / TEM converter according to the invention is designed so that a microwave in TE mode which arrives at the TE / TEM converter through a waveguide channel is reflected towards the portions with dimensional change in partly the transition channel 8 and partly the transition foil 20. Hereby first and second reflection waves are formed. same amplitude and frequency but are in opposite phase, so they cancel each other out. Thanks to the energy conservation principle, the microwave is thus forced further into the TE / TEM converter, whereby it follows the foil edge and the gap between the foil edge and the opposite channel wall. For this, it is forced to change mode to TEM mode. The reverse process occurs when a microwave in TEM mode arrives at the TE / TEM converter.

The TE / TEM converter is designed to operate for microwaves within a limited frequency range because ... n v-.

I n »fl> sna 10 15 20 25 30 35 o n s». o a. n. .o 523 244. , f - n f n. oc. 24 it is not possible to provide a geometry that generates reflection waves that cancel each other out for all frequencies within the microway area simultaneously. Furthermore, the dimension of the waveguide channel before and after the TE / TEM converter depends on the frequency of the microwaves and in some cases on a connecting application.

The dimensions of the TE / TEM converter can be determined as follows.

First, the center frequency and bandwidth of the desired incident signal are selected. Then the width and height of the TEM section are selected, taking into account that the structure must be below the cutoff for the highest applicable frequency that is relevant. Then the number of transformation steps in the guide or foil is selected, depending on the selected design. Then select the slope and length of the foil or the size and length of the foil steps to minimize the reflection. The structure is then suitably optimized in a computer.

A general example of a microwave component comprising two TE / TEM converters 6 of the type described above is a transducer device according to the invention.

A first embodiment of a transducer device according to the invention with a low-pass waveguide filter 37 is shown in Figs. 8-11. Such a device thus constitutes a low-pass filter for microwaves in TEM mode which can be directly connected to the surrounding structure for microwaves in TE mode.

The transducer device comprises a device block 33 with a device channel 34. The device block 33 comprises a first device block half 35 and a second, with the first complementary device block half 36. In each device block half 35, 36 one half of the device channel 34 is milled. When the device block halves 35, 36 are joined, the device channel halves are opposite each other and form the device channel 34.

The division plane 5 of the device block halves 35, 36 constitutes the E-plane of the transducer device. 10 15 20 25 30 35. . The transformer device according to the invention comprises a first TE / TEM converter 6 and a second TE / TEM converter 6 and a TEM section in the form of a low-pass waveguide filter 37 for microwaves in TEM mode. between them. The TEM section 37 comprises a metal block 42 with a TEM channel in the form of a low-pass waveguide filter channel 43 and a TEM foil in the form of a low-pass waveguide filter foil 44.

In the example shown, the TE / TEM converters 6 are the same and designed according to the first embodiment above, for which reason reference is made here to the description above. However, they may be designed in any of the ways described above and need not be the same, cf. Fig. 12 where one TE / TEM converter has taped foil and the other TE / TEM converter has stepped foil. In many applications, it is an advantage to design them differently in order to optimize them for the relevant application. For all possible embodiments and variants of the converter device TE / TEM converter, reference is made to the description above.

The low-pass filter, or TEM section 37, has a first TEM port 38 and a second TEM port 39. The first TE / TEM converter 6 is connected to the first TEM port 38 of the TEM section 37 with its TEM port 10. The second TE / TEM converter 6 is connected to the second TEM port 39 of the TEM section 37 with its TEM port 10.

The transducer device according to the invention further has a first outer TE port 40 and a second outer TE port 41 for the passage of microwaves in TE mode. The first external TE port 40 of the converter device is connected to the TE port 9 of the first TE / TEM converter 6 and the second external TE port 41 of the converter device is connected to the TE port 9 of the second TE / TEM converter 6.

The first and the second TE / TEM converter 6 and the low-pass filter 37 are integrated, ie they do not constitute separate interconnected components, but are made in common pieces. A portion of the converter block 33 .nu n. »Nn-n 10 15 20 25 30 35,,. ,. , Q ø a u nu 523 244. | v u u o \. - '_. ,. »Q ons 26 thus consists of the block halves 42 of the low-pass filter 37 and a portion on each side if this consists of the block halves 3, 4 of each TE / TEM converter 6.

Furthermore, the transition channels 8 of the first and second TE / TEM converters 6 form portions of the device channel 34 as well as the TEM channel, or the low pass waveguide filter channel 43, form a portion of the device channel 34 located between the transition channels 8. The low pass waveguide filter channels 43 have a smaller .

The transducer device comprises a device foil 45 in two parts 45a and 45b shown in Fig. 11. One portion of the device foil 45a is the transition foil 20 of the first TE / TEM converter 6 and another portion of the device foil 45a is the transition foil 20 of the second TE / TEM converter 6. Between these portions are the low pass waveguide filter foil 44. in one piece.

The second portion 45b of the device foil includes the spacer foils 21 of the TE / TEM converters 6 and a second portion of the low pass waveguide filter foil 44 therebetween.

The low-pass waveguide filter foil 44 thus comprises in the example shown two parts which are each provided with TEM resonators 50. The low-pass waveguide filter foil has antiparallel TEM resonators in the example shown, but it is also possible to use only some low-pass waveguide filter foils with parallel TEM resonators .

The device foil 45a, b is designed to fit between the device block halves 35, 36 in the same way as the transition foil 20 and the spacer foil 21 are designed to fit between the transducer block halves 3, 4 as described above.

When the transducer device is mounted, the portions of the transition foil 8 of the device foil 8 are located between the portions of the device block halves 35, 36 which each belong to the TE / TEM transducers 6 as well as u u .nu n.;> ~. | 10 15 20 25 30 35 «s2s 244,. n ø n a u n un: a 27 low-pass waveguide filter foil 44 is located between the device block halves at the low-pass waveguide filter 37.

As described above, at least a portion of the transition foils 20 are in the transition channel 8.

The TEM foil 44 is in the first embodiment designed as a low-pass waveguide filter foil, but may be designed in other ways depending on the application which is intended to be provided in the TEM section 42.

There are many different possible applications for the TEM section.

Fig. 13 shows a transducer device according to the invention where the TEM section comprises a damper.

The two parts of the device foil 45 are provided at the TEM foils 44 with a resistive film 46 which also covers the gap between the TEM foils.

Fig. 14 shows a transducer device according to the invention where the TEM section comprises a switch in two different views and an associated device foil. A PIN diode 47 is connected partly to the TEM foil 44 and partly to a bias connection 48.

Fig. 15 shows a diplexer comprising three converter devices 51 according to the invention with low-pass waveguide filter 37 and TE / TEM converter 6.

The diplexer is of a type described in the Swedish patent application SE 0002521-3. It includes an antenna port 52, a receiver port 53 and a transmitter port 54.

Through these ports 52, 53, 54, microwaves pass in TE mode.

Each port 52, 53, 54 is connected to a transducer device 51. The three transducer devices 51 are designed according to the embodiment shown in Figs. 8-11, but they may be designed in any other of the ways described above.

The diplexer further includes a filter section 55 for microwaves in TE mode. The filtration section 55 has a filtration channel 59 with three TE ports, namely a TE nozzle; 10 15 20 25 30 35,. . ,,. - n o o o; n o 52z 244. n - n a a | o n an una 28 antenna port 56, a TE transmitter port 57 and a TE receiver port 58.

The first external TE port 40 of a first transducer device 51 is connected to the TE antenna port 56, the first external TE port 40 of a second transducer device 51 is connected to the TE transmitter port 57, and the first external TE port 40 of a third transducer device is connected to the TE the receiver port 58. The second external TE port 41 of the first transducer device 51 is connected to the antenna port 52, the second external TE port 41 of the second transducer device 51 is connected to the transmitter port 53 and the second external TE port 41 of the third transducer device is connected to the receiver port 54.

The transducer devices 51 and the filtration section 55 are integrated with each other. The entire diplexer thus comprises a diplexer block with a first diplexer block half 60 and a second, with the first diplexer block half 60 complementary diplexer block half (not shown). When the diplexer block halves are connected to each other, a diplexer channel 62 is formed. The diplexer channel 62 comprises the filtration channel 59 and the three device channels 34. Each device channel 34 comprises a first and a second transition channel 8 and a TEM channel 43 .

The diplexer foil 61 comprises a filtration foil 63 which is provided with sparking poles 64 which are arranged in the filtration channel 59 when the diplexer foil 61 is mounted in the diplexer. In connection with the filtering foil 63, the diplexer foil 61 comprises the three device foils, which are formed in the manner described in connection with the first embodiment of the converter device.

Thus, in the embodiment shown here, a portion 65 of the diplexer foil 61 has the function of a spacer foil. : av 10 523 244 a n ø c u n I I nu un. However, it is possible to design the transducer devices included in the diplexer in any of the other ways described above.

In the mounted diplexer, the portion of the diplexer foil 62 with filtration foil 63 is located between the diplexer block halves 60, 61 in the filtration section 55 and at least partially in the filtration channel 59.

The portions of the diplexer foil 62 with device foil 43 are located between the diplexer block halves 60, 61 and at least partially in the device channels 34. ø o o u nu

Claims (30)

mur »10 15 20 25 30 35 | n n | | I o ~ o v en o (523 244 1............ .. 30 PATENT CLAIMS A TE / TEM converter comprising a transition section (7) with a TE port (9) for passage of microwaves in TE mode and a TEM port (10) for passage of microwaves in TEM mode, the transition section (7 ) is arranged to cause at least substantially the entire microwave arriving via either port (9, 10) to pass through the transition section (7) during conversion of the microwave from either of said TE and TEM modes to the other mode, characterized in that the transition section (7) is arranged to generate from said arriving microwave, during its passage through the transition section (7), several reflection waves which take each other out. A TE / TEM transducer according to claim 1, wherein the transition section (7) is arranged to generate in parallel of said incoming microwave first and second reflection waves, which take each other out. A TE / TEM converter according to claim 1 or 2, wherein the transition section (7) comprises a transition channel (8) and a transition foil (20) arranged in the transition channel (8), the transition channel (8) and the transition foil (20) each. comprises at least one dimensional change, which dimensional changes are so adapted to each other that from said incoming microwave the transition foil (20) generates first reflection waves and the transition channel (8) generates second reflection waves, which first and second reflection waves cancel each other out. A TE / TEM converter according to claim 3, wherein the transition channel (8) extends from the TE port (9) to the TEM port (10) and has a larger cross section at the TE port (9) than at the TEM port ( 10). A TE / TEM converter according to claim 4, wherein the transition section (8) has an E-plane; and wherein the transition foil (20) is arranged in the middle of the transition channel un von n. 10 15 20 25 30 35 n Q ø nau ø 0 IU 00 523 244 uj "1 ''. | ø n 0 I n u. 31 (8) with its plane in the E-plane and has a height B across the transition channel (8) which is smaller at the TE gate (9) than at the TEM gate (10). A TE / TEM converter according to claim 5, wherein the transition channel (8) has a rectangular cross section with a width a perpendicular to the E-plane, a height b parallel to the E-plane and at least two steps (II) between the TE gate ( 9) and the TEM port (10) so that the width a and / or height b of the transition channel (8) gradually decreases from the TE port (9) towards the TEM port (10). A TE / TEM converter according to claim 6, wherein the transition channel (8) has a longitudinal center axis and the width a and / or height b of the transition channel (8) is symmetrical with respect to the center axis. A TE / TEM converter according to claim 5, wherein the transition channel (8) has a rectangular cross-section with a width a perpendicular to the E-plane and a height b parallel to the E-plane, and four longitudinal channel walls (14, 15, 16, 17) and wherein a tapering (32) is formed on one or more of the channel walls (14, 15, 16, 17), so that the width a and / or height b of the transition channel (8) continuously decreases in the direction from the TE gate (9). ) towards the TEM port (10). A TE / TEM transducer according to any one of claims 5-8, wherein the transition foil (20) comprises at least one step (31) between the TE gate (9) and the TEM gate (10) so that the height B of the transition foil (20) is stepwise increases from the TE port (9) to the TEM port (10). A TE / TEM converter according to any one of claims 5-7, wherein the transition foil (20) comprises a tapered portion (24) in which the height B of the transition foil (20) continuously increases from the TE gate (9) towards the TEM gate (10). . A TE / TEM transducer according to any one of claims 5-10, further comprising a first transducer block half (3) having a first transition channel half, a second transducer block half (4) complementary to the first transducer block half (4) having a second transition channel half, 15 20 25 30 35 vonn en i 523 244 g; Which are connected to each other to form the transition channel (8) and wherein the transition foil (20) is arranged between the transition channel halves (3, 4) with at least one portion in the transition channel (8). The converter device comprising a first and a second TE / TEM converter (6) according to claim 1, further comprising a TEM section (37) for microwaves in TEM mode with a first and a second TEM port (38, 39 ) for passage of microwaves in TEM mode, the first TE / TEM converter (6) being connected to the first TEM port (38) of the TEM section (37) with its TEM port (10) of its transition section (7) and the second TE / TEM converter (6) is connected to the second TEM port of the TEM section (37) its transition section (7) TEM port (10). The transducer device of claim 12, further comprising (39) a first and a second outer TE port (40, 41) for passage of microwaves in TE mode, the first outer TE port (40) of the transducer device being connected to the port (41) of the first TE / TEM converter (6) The TE port (41) is connected to the TE port (9) of the second TE / TEM converter (6). A converter device according to claim 12 or 13, wherein the first TE / TEM converter (6), the second TE / TEM converter (6) and the TEM section (37) are and wherein the second outer port of the converter device is TE-integrated. A transducer device according to claim 14, wherein the TE / TEM transducers (6) each comprise a transition channel (8); The TEM section (37) includes a TEM channel (43); the transducer device comprises a device channel (34) comprising the transition channels (8) and the TEM channel (43); the transducer device further comprises a first device block half (35) device channel half and a second, with the first device block half (35) complementary and wherein with a first min; 10 15 20 25 30 35 Q - v 4 no,. | ; c i i! The device block halves (36) have a second device channel half, the device block halves (35, 36) being interconnected to form the device channel (34). The transducer device of claim 15, wherein the TE / TEM transducers (6) each comprise a transition foil (20); the transducer device further comprises a device foil (45) which is integral with the transition foils (20); and wherein the device foil (45) is arranged between the device block halves (35, 36) with its plane in the E-plane and with at least one portion in the device channel (34). A converter device according to any one of claims 12-16, wherein the first and the second TE / TEM converter (6) are equal and mirror-inverted. A transducer device according to any one of claims 12-17, (37) a low pass waveguide filter. A transducer device according to claims 15 and 18, wherein the TEM section is constituted by a TEM channel (43) constituted by a low-pass waveguide filter channel. The transducer device of claim 15, 16 and 18, wherein the device foil (45) comprises a low pass waveguide filter foil (44). The transducer device of claim 20, wherein the low pass filter foil (44) is provided with TEM resonators. A converter device according to claim 12, wherein the TEM section (37) is constituted by a damper. The transducer device of claim 12, wherein the TEM section (37) is a switch. A diplexer for connecting a transmitter and a receiver to an antenna, comprising at least one transducer device (51) having a low pass waveguide filter (37) for filtering microwaves in TEM mode and a first and a second TE / TEM transducer (6) according to claim 1. The diplexer of claim 24, further comprising an E-plane and further comprising a filtration section (55); 10 15 20 25 30 35. , a v. nnn ø ø oo 523 244; ..... n ... 34 for microwaves in TE mode in connection with at least a first transducer device (51) of said at least one transducer device (51), which filtration section (55) comprises a filtration channel (59) and a filter foil (63) provided with sparking poles (64) and provided with at least one portion of the filter channel (59) with its plane in the E-plane. The diplexer of claim 25, wherein the filtering section (55) has TE ports (56, 57, 58) for passage of microwaves in TE mode; the first transducer device (51) comprises a first outer TE port (40); and wherein the first external TE port (40) of the first transducer device (51) is connected to one of the TE ports (56, 57, 58) of the filtration section (55). The diplexer of claim 26, further comprising a transmitter port (54), a receiver port (53) and an antenna port (52), and a second and a third transducer device (51) of said at least one transducer device (51), each comprising first and second outer TE port (40, 41), the first transducer device (51) further comprising a second outer TE port (41), the filtering section (55) having a TE transmitter port (57), a TE receiving port ( 58) and a TE antenna port (56), the first external TE port (40) of the first transducer device (51) is connected to the TE transmitter port (57) of the filter section (55) and the second external TE port of the first transducer device (51). (41) is connected to the transmitter port (54), the first external TE port (40) of the second transducer device (51) is connected to the TE receiver port (58) of the filter section (55) and the second external TE port of the second transducer device (51). (41) is connected to the receiving port (53), and wherein the first surface of the third transducer device (51) re TE port (40) is connected to the filter section (55) v .aa o »man» 10 15 20 25 30. n u ~ | The TE antenna port (56) and the second external TE port (41) of the third transducer device (51) are connected to the antenna port (52). The diplexer of claim 27, wherein the filtration section (55) and the transducer devices (51) are integrated with each other. The diplexer of claim 28, wherein the transducer devices (51) each comprise device channel (34); the diplexer further comprises a diplexer channel (62) comprising the device channels (34); the diplexer further comprises a first diplexer block half (60) having a first diplexer channel half and a second, with the first diplexer block half complementary diplexer block half with a second diplexer channel half, which diplexer block halves are interconnected to form the diplexer channel (62); and wherein the pitch plane of the diplexer block halves (60) is the E plane. The diplexer of claim 29, wherein the transducer anodes each comprise device foil (45); the diplexer further comprises a diplexer foil (61); the diplexer foil (61) is integral with the device foils (45) and the filtration foil (63); and wherein the diplexer foil (61) is disposed between the diplexer block halves (60) with its plane in the E-plane and with at least one portion in the diplexer channel (62). .nu nl