[0001] This invention relates to a microwave switch which is suitable for controlling microwave
energy in a waveguide system. It is particularly difficult to fabricate a microwave
switch which is compatible with waveguide structures as this generally requires the
provision of high precision moving parts. As an alternative, it has been proposed
to utilise a fin line structure, as it is possible to electrically control the conductivity
of such a structure without the need to provide mechanically movable parts. Switchable
diodes can be used to short circuit opposing edges of a fin line structure, when it
is required to render the switch non-conductive. Fin line structures are described
in, for example, "Integrated Fin Line Millimeter Components" by P. J. Meier, IEEE
Transactions on Microwave Theory and Techniques, Vol. MTT-22, No. 12, Dec. 74. Microwave
switches which incorporate fin line structures have not been capable of providing
a very high level of electrical performance and in particular in the off state, i.e.
when the switch is nominally non-conductive, the impedance which it presents to an
applied microwave signal is not sufficiently high for many purposes, as this can have
the effect of allowing a relatively low level electrical signal to reach a load. Even
though the level of this leakage signal is low, it is very undesirable and quite unacceptable
for certain applications. The present invention seeks to provide an improved microwave
switch in which this drawback is reduced.
[0002] According to this invention, a microwave switch for controlling the passage of microwave
energy includes a waveguide channel dimensioned to support a predetermined waveguide
mode of propagation of the microwave energy applied to it; a fin line structure, dimensioned
to support a slot line mode of propagation, comprising a pair of co-planar conductive
plates mounted across the waveguide channel and lying in the E plane, the two plates
being spaced apart by a small distance; switchable means arranged to control the conductivity
of the fin line structure; and means for locally modifying the waveguide channel in
the vicinity of the fin line structure so as to render it incapable of supporting
said predetermined waveguide mode so that the microwave energy is diverted to said
fin line structure.
[0003] Preferably the means for locally modifying the waveguide channel comprises a portion
of the waveguide channel in which its height, in a direction perpendicular to the
E plane direction, is very much reduced in the region of the fin line structure. This
can be achieved by locally deforming the outer wall of the waveguide channel or alternatively
by inserting into the channel a suitably shaped conductive plate or block. The presence
of the means for locally modifying the waveguide channel prevents propagation of the
fundamental waveguide mode and ensures that the applied microwave energy is diverted
to the fin line structure so that it can be controlled by the switchable means by
the switching arrangement.
[0004] Harmonic waveguide modes of propagation may be generated to a certain extent, although
their amplitude as compared with that of the fundamental mode is very small.as in
a conventional switch utilising a fin line structure.
[0005] The means for locally modifying the waveguide channel also suppresses these harmonic
modes. To further improve the attenuation of the harmonic modes, an absorbtive (lossy)
material is mounted in cavities positioned in the vicinity of the fin line structure.
[0006] The switchable means can comprise one or more switchable diodes mounted to bridge
the two plates cf the fin line structure - these can be termed shunt mounted diodes.
At relatively l
CN microwave frequencies, microwave energy passes through the switch whilst the diode
(or diodes) is non-conductive, whereas it is reflected back to the input port whilst
the diode is held in its conductive state.
[0007] Because all diodes possess inductance, the effect can be reversed at higher frequencies;
that is to say, the switch is conductive whilst the diode is conductive and vice versa.
Thus the switchable means has to be designed with the operating frequencies of the
switch in mind.
[0008] Instead of using shunt mounted diodes, it is possible to mount one or more diodes
to bridge discontinuities in one or both of the two plates which comprise the fin
line structure. Such an arrangement of diodes is termed series mounted diodes.
[0009] The microwave switch can be used to route energy to different ones of a plurality
of input or output ports, as opposed to operating as a simple on-off switch.
[0010] The invention is further described by way of example with reference to the accompanying
drawings in which,
Figures 1 and 2 show sectional and perspective views respectively of a known microwave
switch, and
Figure 3 shows a perspective view of a microwave switch in accordance with this invention,
and
Figure 4 shows an alternative kind of switch.
[0011] Referring to Figure 1, which shows a sectional view, and Figure 2 which is an exploded
perspective view, a microwave switch comprises two large blocks of conductive material
2 and 3 which are arranged to sandwich between them a fin line structure 4. Thin sheets
of dielectric material 24, 25 are positioned on either side of the fin line structure
4, so as to electrically insulate it from the two blocks 2 and 3. In use, microwave
energy is applied to an input port 5 of a microwave channel 6, which is dimensioned
so as to support a predetermined waveguide mode of propagation. In this connection
the term microwave includes millimetric frequencies. The fin line structure 4 consists
of two coplanar plates 7 and 8 mounted in the E plane direction of the waveguide channel
6. For convenience the plates 7 and 8 are supported by the larger dielectric sheet
24. In some cases it may be more convenient to form the plates 7 and 8 respectively
as thin conductive foils on opposite sides of a single thin insulating film of dielectric
material - as the film is very thin, the. two plates are still effectively coplanar.
The fin line has the effect of converting the waveguide mode of propagation to a slot
line mode of propagation, and the two plates 7 and 8 are provided with edges surfaces
9 and 10 of a tapering profile adjacent to the input port 5 so as to avoid abrupt
transitions occurring in the propagation of the microwave energy. Thus the microwave
energy travels over the central portion of the fin line structure in a slot line mode,
and is then progressively converted back to a waveguide mode of propagation by a further
pair of tapering edges 11 and 12, so that theoriginal waveguide mode of propagation
is made available at an output port 13 of the waveguide channel 6.
[0012] Two diodes 14 and 15 are mounted so as to elerically bridge the two plates 7 and
8, and bias circuits 16 and 17 (which may include suitable filters) are arranged so
as to permit the two diodes to be either biassed into conduction or non-conduction
depending on the polarity and magnitude of bias voltages applied at contacts 18 and
19. If the two diodes 14 and 15 are held non-conductive, the microwave energy applied
at input port 5 travels through the switch to a load (not shown) via port 6 with very
little attenuation. However, if the two dicdes are rendered conductive, the microwave
energy is reflected back to its source and very little energy reaches the load. Additional
diodes can be provided to enhance the switching action if needed.
[0013] To minimise the loss of microwave energy whilst the switch is in its conductive state,
two r.f. choke circuits in the form of cavities 20 and 21 are provided. The thickness
of the wall "T" is made equal to λ/4 where λ is the wavelength of the applied signal.
These cavities operate to ensure the existence of an effective radio frequency short
circuit between the fin line structure itself and the adjacent waveguide walls. Unfortunately,
although these chokes are essential, their presence enables many more modes of propagation
to exist. In particular, harmonic modes of propagation can now by-pass the fin line
structure and reach a load even whilst the switch is nominally in its non-conductive
state.
[0014] These leakage levels of microwave energy can be very small indeed, but are still
unacceptable for certain applications. A microwave switch which is modified in accordance
with this invention is illustrated in Figure 3, and it permits the performance level
to be substantially enhanced to levels which enable very stringent performance requirements
to be met.
[0015] Referring to Figure 3, the reference numerals of Figures 1 and 2 are used to identify
like parts. The main point of difference shown in Figure 3 comprises two side wall
blocks 30 mounted adjacent to the fin line structure (part of the cavity wall is cut
away so that one block 30 can be seen, but the other block, which is mounted within
the block 3, is not visible). Each block has a height which is somewhat less than
the corresponding depth of the waveguide channel so that the tops of the blocks do
not contact the fin line structure itself. Each end of each block 30 is tapered as
shown, to give a more gradual transition to and from the slot line mode. Although
in this example, both blocks 30 are electrically connected to the walls of the channels
6, they can be electrically insulated from it. Both blocks 30, are however, formed
of a material having a good electrical conductivity. The presence of these blocks
prevents propagation of the waveguide mode along the waveguide channel, and forces
the microwave energy wholly into a slot line mode, so that it is conducted along the
fin line structure. In this way virtually all of the energy applied to the switch
is controlled by the action of the diodes 14 and 15.
[0016] Even so, some of the harmonic modes continue to exist and these can by-pass the fin
line structure by passing along the choke cavifies 20 and 21. Lossy absorbent material
33 and 34 is positioned in each choke cavity to absorb this energy and to prevent
the excitation of harmonic modes of any appreciable energy. Similar blocks, not shown,
are mounted in the waveguide structure 3 in an exactly analogous manner.
[0017] Any suitable lossy material can be used, such as Marconi Absorber type Y33-1980.
[0018] The effect of the side wall blocks 30 and the lossy material is to very greatly enhance
the performance of the switch. Although the conductivity of the switch in its "on"
state remains very high, its effective transmissive impedance in the "off" state becomes
very high indeed, and reduces energy leakage to a load of harmonic modes to an extremely
low level.
[0019] A three port switch is shown in Figure 4. It has one input port 32, and two output
ports 33 and 34. The general principle of operation is very similar to that of the
switch shown in Figure 3, but three waveguide channels 35, 36, 37 meet at a point
where a side wall block 38 is positioned. In Figure 4, only the bottom half of the
switch structure is shown, and in practice an additional block is placed above that
of the block 38, with a fin line structure between them. As before,the block 38 has
tapered ends 39, 40, 41. The fin line structure is shown in broken line - it consists
of three plates 42, 43, 44, with the plates being bridged by switchable diodes 45,
46 placed in the two channels 36, 37 leading to the output ports 33, 34. By controlling
the state of the diodes, microwave energy can be routed to either output port, or
even shared between them. Absorbtive (lossy) material 47, 48, 49 is positioned in
cavities 50, 51, 52 adjacent to the fin line structure, in a manner analogous to that
of Figure 3.
1. A microwave switch including a waveguide channel (6) dimensioned to support a predetermined
waveguide mode of propagation of the microwave energy applied to it; a fin line structure
(4), dimensioned to support a slot line mode of propagation, comprising a pair of
co-planar conductive plates (7,8) mounted across the waveguide channel and lying in
the E plane, the two plates being spaced apart by a small distance; switchable means
(14,15) arranged to control the conductivity of the switch; and means (30) for locally
modifying the waveguide channel in the vicinity of the fin line structure so as to
render it incapable of supporting said predetermined waveguide mode so that the microwave
energy is diverted to said fin line structure.
2. A switch as claimed in claim 1 and wherein the means for locally modifying the
waveguide channel comprises a portion of the waveguide channel in which its height,
in a direction perpendicular to the E plane direction, is very much reduced in the
region of the fin line structure.
3. A switch as claimed in claim 2 and wherein the means for locally modifying the
waveguide channel comprise a pair of conductive blocks, one mounted on either side
of said fin line structure.
4. A switch as claimed in claim 3 and wherein the ends of the blocks are shaped so
as to present tapered transition regions to the input and output ports of the switch.
5. A switch as claimed in claim 3 or 4 and wherein the blocks are electrically connected
to the waveguide channel.
6. A switch as claimed in any of the preceding claims and wherein a pair of choke
cavities are provided externally of the waveguide channel in the region of the fin
line structure, and wherein each choke cavity contains lossy material so as to attenuate
harmonic modes of the microwave energy applied to the switch.