Compact multiport waveguide switches

A waveguide switch based on alternating short and open loads in a waveguide path. In one embodiment, the switch being made up of four waveguides connected by sections of ridge waveguides where simple short-circuit loads can be activated to control the signal paths. The switch being adapted for the C-, R- and T-type switches. Another embodiment of the same device being adapted for SPT type switched.

FIELD OF THE INVENTION

The present invention is related to microwave switches and more particularly to the realization of miniature multiport waveguide switches for high power applications.

BACKGROUND OF THE INVENTION

Waveguide switches are used in a broad range of applications with two main functions: They are used either to route signals for connecting the appropriate network elements or to provide redundancy schemes. Many spacecraft systems incorporate sophisticated switch matrices in order to increase the system reliability. They provide redundancy connections which are activated to bypass failing devices either automatically or by ground terminal commands.

The switching networks are relatively easy to realize at low frequencies and at low signal power levels. The switches for low power applications are typically implemented using coaxial technology. Waveguide switches, on the other hand, are preferred in high frequency and for high power applications. However, when several ports are involved, signal routing in waveguide switches (such as changes in the propagation direction or signal crossovers) are more difficult to implement limiting the use of conventional waveguide switches to C and R switches. At the same time, since mass and volume must be kept to a minimum in many applications such as satellite systems, there are demands for new improved compact switch designs with more advanced functionality.

Several waveguide switches have been proposed for RF and microwave systems. Many of them are based on the rotation of a junction or waveguide section inside the main body of the device. They are either manually operated or controlled by electromechanical systems. In this last case, they have an internal mechanical linkage with a motor or a rotary solenoid for automated actuation (e.g., U.S. Pat. No. 4,967,170).

Ridge waveguides were combined with MEMS switches for the realization of simple switch configurations such as SPST, SP2T and C-switches [U.S. Pat. No. 7,292,125]. The structures proposed in prior art, such as those in U.S. Pat. Nos. 4,967,170 and 7,292,125, cannot be easily employed in the realization of waveguide T-switches or switches with relatively large number of ports such as SP4T or SP6T switches. The availability of such waveguide switches makes it possible to realize highly advanced compact switch matrices with fewer elements.

SUMMARY OF THE INVENTION

The present invention provides a novel mechanism to implement waveguide switches. Instead of using rotating junctions, the switch is based on alternating short and open circuits in the propagation direction of the ridge waveguides. The shorts can be provided with a variety of very simple elements. Four-port C and R-type and, most importantly, T-type switches are provided using the same short circuit load concept. All the types are addressed with a very compact layout. These switches have the advantage of having simplicity of the operation. The structure does not require mechanical rotation of the junctions and maintains a very compact layout. All the port interconnections required for the T-switch are addressed.

In another embodiment of the same invention, a new ridge waveguide junction is proposed that allows the interface of waveguide port to several waveguide ports over a relatively large bandwidth. The junction makes possible to realize highly compact SPNT waveguide switches, such as SP4T and SP6T switches.

DETAILED DESCRIPTION OF THE DRAWINGS

FIG. 1shows a waveguide rotary switch (prior art). The body of switch1has four waveguide ports denoted by A, B, C and D. The switch uses a rotary mechanism2that rotates around its axis to create waveguide paths between the ports to establish the three states of the R-switch. For example, in state I, the rotary mechanism is turned such that to establish transmission between port A and port B and simultaneously establish transmission between port C and port D.

FIG. 2shows a waveguide Single-Pole Single Through (SPST) switch (prior art) consisting of a ridge waveguide and two waveguide to ridge waveguide transformers. A set of short circuit loads5are used to connect the ridge3to the housing6.

FIG. 3shows a waveguide C-switch (prior art) comprising of four waveguide ports, sections of ridge waveguides3and four waveguide to ridge-waveguide transformers. Four sets of short circuits loads that can be actuated to provide a short circuit between the ridge and the switch housing6. The switch has two states. In state I, there is a transmission of microwave signal between port 1 and port 2 and port 3 and port 4, while in state II, there is a transmission between port 1 and port 4 and transmission between port 2 and port 3.

FIG. 4shows a 3-dimensional view (FIG. 4a) and a side view (FIG. 4b) of waveguide switch for explaining the operation of the present invention. The structure has three ports P1, P2 and P3. An E-plane bifurcation of the rectangular waveguide enclosure7is achieved by a metal septum8having ridges on the top and bottom side of the septum. Short circuit loads10aand10bare marked by black dot inFIG. 4. One short circuit load10ais located on the top side of the metallic septum and another one10bis located on the bottom side of the metallic septum. The ridge waveguide dimensions are optimized such that the microwave signal is directed from port P1 to port P3 while port P2 is kept isolated when the short circuit load10ais used. When the short circuit load10bis used the microwave signal is directed from P1-P2, while P3 is isolated. To illustrate the concept the short circuit loads are provided by screws attached to the waveguide enclosure that can be turned in to connect the ridges to the enclosure7. Other elements could provide this short circuit load, the screw is the simplest solution to illustrate the concept.

FIG. 5ashows one embodiment of the present invention. It is a C-type switch with two states (FIG. 5b). In state I, connections are established between P1-P2 and P3-P4, while in state II the connections are between P1-P4 and P2-P3. The whole C-switch structure is symmetric with respect to the septum8which has ridges9on the top and bottom of its surface. The two states are activated by four short circuit loads10a,10b,10cand10d. There are two short circuit elements per top/bottom layer of the septum. Only two shorts are activated at the same time to realize one state. In state I the short circuit loads10dand10bare used to provide connections between P1-P2 and P3-P4. While in state II, the short circuit connections10aand10care used to provide connection between P1-P4 and P2-P3.

FIG. 6ashows a configuration similar to that shown inFIG. 5ato realize an R-switch. The R-switch has three states as illustrated inFIG. 6b. In state I, connections are established between P1-P2 and P3-P4, while in state II the connections are between P1-P4 and P2-P3. In state III connection are provided only between P1-P3. The three states are activated by six short circuit loads10a,10b,10c,10d,10eand10f. There are three short circuit elements per top/bottom layer of the septum. Only two shorts are activated at the same time to realize one state. In state I the short circuit loads10dand10bare used to provide connections between P1-P2 and P3-P4. While in state II, the short circuit connections10aand10care used to provide connection between P1-P4 and P2-P3. In state III, the short circuit loads10eand10fare used to provide connection between P1-P3.

FIG. 7ashows a 3-dimensional view of a T-waveguide switch. The switch has 4 ports P1, P2, P3 and P4 and operating in three states as shown inFIG. 7b. In state I, connections are established between P1-P2 and P3-P4, while in state II the connections are between P1-P4 and P2-P3. In state III connection are provided between P1-P3 and P2-P4. The whole T-switch waveguide enclosure7is symmetric with respect to the septum8, which has ridges9on top and bottom of its surfaces. The three states are controlled by 10 short circuit loads10a,10b,10c,10d,10e,10f,10g,10h,10iand10j. There are five short circuit elements per top/bottom layer of the septum.4shorts are activated at the same time to realize states I and II,6shorts are activated to realize state III. In state I the short circuit loads10b,10j,10dand10gare used to provide connections between P1-P2 and P3-P4. While in state II, the short circuit connections10a,10i,10cand10hare used to provide connection between P1-P4 and P2-P3. In state III the short circuit loads10eand10f, with10a,10d10h,10j, are used to provide connection between P1-P3 and P2-P4.

FIG. 8shows a T-waveguide switch fabricated according toFIG. 7. The switch consists of identical top lid and bottom lid. The septum8with the ridges9is fabricated with corners, along with the top and bottom lid to form the waveguide housing7. The three sections are bolted together to form the T-switch. Five screws holes are made on each lid to introduce the short circuit loads. The T-Switch has been tested demonstrating excellent results.

FIG. 9shows an embodiment of a Single-Pole Four Through (SP4T) switch.FIG. 9ashows the top view whileFIG. 9billustrates a 3-dimensional view of the switch. It consists of an input port P1 and four output ports P2, P3, P4 and P5. The ports are interfaced to ridge waveguides11. The ridges are attached to the switch enclosure7. Four short circuit elements12a,12b,12cand12dare located in the gaps between the ridges and the enclosure to provide a short circuit between the enclosure and the ridges. The transmission between the input port P1 to the four ports is enabled by the 1-to-4 ridge waveguide junction13. Three short circuit elements are used at the same time to realize the switch states. The short circuit elements12b,12cand12dare used to provide transmission between P1-P2, while the short-circuit elements12a,12cand12dare used to provide transmission between P1-P3.

FIG. 10shows an SP6T waveguide switch. It consists of an input port P1 and six output ports: P2, P3, P4, P5, P6 and P7. The ports are interfaced to ridge waveguides, where the ridges are attached to the switch enclosure7. Six short circuit elements12a,12b,12c,12d,12e, and12fare located in the gaps between the ridges and the enclosure to provide a short circuit between the enclosure and the ridges. The transmission between the input port P1 to the six ports is enabled by the ridge waveguide junction14. Five short circuit elements are used at the same time to realize the switch states. The short circuit elements12b,12c,12d,12eand12fare used to provide transmission between P1-P2.

FIG. 11shows an SP6T waveguide switch fabricated according toFIG. 10. The switch consists of two lids. The top lid has the input port P1 and the ridge waveguides11. The two lids are bolted together to form the waveguide ports. The ports are built-in with waveguide to coaxial transitions so that the input and output ports have coaxial interface. The SP6T switch has been tested demonstrating excellent results.