SE516031C2 - Switchable microwave device - Google Patents

Abstract

A planar microwave device such as a transmission line comprises a patterned electrically conducting layer located on a dielectric layer (1) of uniform thickness. A central microstrip line (9) is enclosed by lateral (11) strips which are located on each side of the central strip and are connected to the central strip by bridge portions (15) to form windows (13). Each lateral strip has an interrupt region (17) located between the bridge regions. The interrupt regions can all be switched between an electrically conducting state and an electrically non-conducting or high resistance state. The state changes will affect the characteristic impedance of the transmission line in order to make it work e.g. in a transistor-like fashion or a switchable filter or inductor. The electrically conducting material can be a superconductor and the interrupt regions then contain Josephson junctions or superconducting weak links. Furthermore, the electrically conducting material can instead be a normal conductor and the interrupt regions can then comprise a photoconductive material.

Description

25 30 35 o o a ø. o u - n ø ~ - ~ ø v o o. 516 oz 2 electrically conductive materials. In a preferred geometric design, the lateral strip-shaped conduits are separated from the central microstrip line by windows, which in the longitudinal direction of the central microstrip line are closed by bridge areas.

Each adjacent strip line has an interrupt region located between the bridge wire regions, and the interrupt regions can all be switched between an electrically conductive state and a non-electrically conductive state or a state of high resistance. In a first case, the electrically conductive material is a superconducting material and the interrupt regions then contain Josephson junctions or superconducting weak links. In a second case, the electrically conductive material is a normal conductor and the interruption areas include a photoconductive material.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described as non-limiting embodiments with reference to the accompanying drawings, in which: Fig. 1 is a diagram showing voltage / current curves for a transmission line for different values of the characteristic impedance, - Figs. Fig. 2 is a perspective view of a planar switchable microwave transmission line with impedance which can be changed between two different values, Fig. 3 is a side view of another embodiment of a planar switchable microwave transmission line, and Fig. 4 is a perspective view of a plane switchable microwave transmission line with an impedance that can be changed between three different values.

DESCRIPTION OF THE PREFERRED EMBODIMENT A piece of a microstrip line or of other types of strip lines has a characteristic impedance ZO, which is given by (1) R + imL. = --_- = Z 1Z ii G + mc oR J 'or where R, G, L and C are the line resistance, -conductance, -inductance and -capacitance of the strip line It is observed that for low frequencies the impedance ZO mainly depends of the resistive properties of the line, while for high frequencies such as microwave frequencies the impedance mainly depends on the inductive capacitive properties of the line, ie Zo (2) By thus controlling the inductance and / or capacitance of a strip line, a characteristic impedance Z0 can be changed , which results in a change of the bias / current curve, as shown in fi g. l. A specific change in the absolute value of the characteristic impedance can be obtained by designing the device in an appropriate manner. For example, the mentioned Swedish patent applications are accompanied by a change in the inductance of the magnitude 40 u ø u u - n u ø u u: n - -. . o o Q o u u - ø o v now 516 051 3 order 1: 2 of a certain small change of the capacitance, which results in a change of the impedance of about h / É z 1_4, which may be insufficient for many applications.

However, in the special design of a microstrip device, which comprises windows as will be described below, relatively large changes in the characteristic impedance can be obtained by a suitable design.

In it i fi g. 2, an electrical substrate 1 is used with an electrically conductive earth layer 3, such as a metal layer of eg Cu, Ag or Au, on its bottom surface, the earth layer covering substantially the entire lower surface in the form of a continuous layer. On the upper surface there is a patterned electrically conductive layer 5. In a first case the patterned electrically conductive layer is a superconductor and in a second case it is made of normal electrically conductive material, for example of a metal such as the same metal as the lower layer, ie of copper, silver or gold. The patterned layer 5 forms a transmission path or propagation path intended for microwaves, which move, for example, in the direction of the arrows 7. The patterned layer 5 has a central web part 9 of uniform width Wi, which defines the direction of propagation. Furthermore, it has lateral strip-shaped areas 11, both of which are of equal width and extend parallel to the central web part, an adjacent strip-shaped area 11 being located on one side of the central web part and the other adjacent strip-shaped area being located on the opposite side of the central web part 9. The adjacent strip-shaped areas 11 are preferably placed symmetrically with respect to the axis of the central web part 9. The adjacent strip-shaped areas 11 are separated from the central web part of windows 13 in the patterned the layer, which thus also has a strip shape and has a uniform width. The distance from an outer edge of an adjacent strip-shaped region to the outer edge of the opposite adjacent strip-shaped region is WO, which is also the effective width of the waveguide, when the adjacent strip-shaped regions are driven to conduct an electromagnetic wave. .

The windows 13 have length b and are closed at their ends by transverse bridge portions 15, which extend from the central web part 9 to the adjacent strip-shaped areas 11. The adjacent strip-shaped areas have at their central parts, which are located centrally in in relation to the bridge portions 15, fields or spacer regions 17 made in a special way or of another specially selected material. The special regions 17 are in the first case designed to form Josephson junctions or superconductor weak links and in the second case comprise a photoconductive material.

In the first case, a localized magnetic field can be generated at the special areas 17 by conducting an electric current at the areas to form a superconducting current loop, as symbolically indicated by the device 19 in fi g. 2. The current can be generated by a voltage unit 21, which is connected to the device 19 via a resistor R and a switch 23, which is controlled by some monitoring circuit or signal control circuit, not shown. The Josephson junctions or the superconducting weak links in the special areas 17 are controlled so that they assume a normal or a superconducting state by means of this current and 5 10 15 20 25 30 35 40 a - n -. o u - ~ - a Q - o ~ u 516 031 4 thereby by means of the monitoring circuit or the control circuit. Instead of control by means of a superconducting current loop, the temperature of the special areas can be controlled, the device 19 then being, for example, a resistive heating element.

In the second case, a light source 25, such as a suitable semiconductor laser, is arranged to emit light towards the particular area, which is then made of photoconductive material, see fi g.3. The light source 25 is connected to and controlled by some monitoring circuit or signal control circuit, not shown. When the light source 25 is activated, it electrically connects the respective adjacent strip-shaped area 11 to each other and turns the strip-shaped area into a continuous or continuous electrical path, while when it is not activated, the adjacent strip-shaped area 11 receives a electrical interruption at the special area 17.

An electromagnetic wave or microwave can propagate along it in fi g. 2 and 3 show the transmission line device. When the special areas 17 function as electrical interruptions, the alternating current in the device is limited due to the microwave in the central strip-shaped area 9 with width Wi. When the special areas act as electrical connections, most of the alternating current, which is derived from the microwave, will instead flow in the adjacent strip-shaped areas 11 depending on the skin effect, the outer edges of the adjacent strip-shaped areas having a distance WO. The inductance per unit length of a microstrip line is mainly determined by the total width W of the line, whereby it can, for example, be approximately inversely proportional to the width W, ie approximately proportional to 1 / W, provided that the height of the microstrip line 5 above its ground plane is fixed. Thus, by changing the state of the spacer regions 17 to make the adjacent strip-shaped areas continuous or interrupted, the inductance L of the microstrip line is also changed. W, provided that the height of the transmission line 5 above its ground plane 3 is fixed for a given dielectric material in the substrate 1. Thus, the characteristic impedance of the transmission line can be changed by changing the effective width W of the line as by providing electrical interruption at the special areas 17, such as described above.

Since the power of a microwave, which propagates along the structure described above, the structure can be used to modulate the microwave by varying the characteristic impedance, which in turn is given by that of the active width of the structure, which is controlled by a monitoring circuit. or signal control circuit. Furthermore, since the power of the control signals required to change the state of, for example, Josephson junctions or superconducting weak links at the particular regions 17 may be much less than the electrical power of a microwave which propagates along the structure, the structure has a amplifying function similar to the function of a transistor.

The i fi g. 2 can generally have a number of lateral strip-shaped areas, which are symmetrically placed on each side of the central strip o o ø n v Q o | n no o u n o u o o v c u o o o. 516 051 5 shaped area, as shown fi g. Each adjacent tubular region 11 then has a particular region or interrupt region 17, the particular regions 17 of a pair of two symmetrically located lateral strip-shaped regions being controlled to simultaneously assume a conductive or non-conductive state or a high resistance state. .

Claims (4)

10 15 516 051 6 PATENT REQUIREMENTS Device comprising a flat transmission line for microwaves with variable transmission characteristics, characterized by a central microstrip line and adjacent strip-shaped lines made of electrically conductive material, the adjacent strip-shaped lines being separated from the central microstrip line by windows, which are closed in the longitudinal direction of the central microstrip line by bridge areas, which electrically connect the central microstrip line and the side-by-side strip-shaped lines, each adjacent strip-shaped line having an interruption area located between the bridge areas, and the areas can be switched between an electrically conductive state and a non-electrically conductive state or a state of high resistance. Device according to claim 1, characterized in that the electrically conductive material is superconducting material and that the interrupt regions comprise a Josephson junction or a superconducting weak link. Device according to claim 1, characterized in that the interruption areas comprise a photoconductive material. Device according to one of Claims 1 to 3, characterized in that the interrupt areas are connected to control circuits via control devices in order to provide a amplifying or modulating function.