FR2531575A1 - Waveguide transition device with dual step end coaxial line and microwave circuit comprising such a device. - Google Patents

Abstract

The invention relates to a device for transition between a waveguide with dual step and an end coaxial line. The transition device according to the invention comprises a waveguide 15a-16a into which is inserted a substrate 12 carrying on each face a conductive strip forming, on the coaxial side 19, a "microstrip" line 13a-14a, and on the waveguide side 20 a bifilar line 13b-14b which is pinched between the two steps 17 and 18 of an adaptation section 15b-16b. The subject of the present invention is mainly applicable to microwave connection circuits.

Description

DOUBLE WAVEGUIDE TRANSITION DEVICE

  REDAN-COAXIAL LINE AT THE END AND CIRCUIT

  MICROWAVE COMPRISING SUCH A DEVICE

  The present invention relates to a device for transitioning from a double step waveguide to a coaxial line at the end, ensuring satisfactory impedance matching between the two transmission lines over a wide frequency band. It also relates to any microwave circuit. comprising such a device. In microwave transmission systems, use is made of transmission devices of different known types such as coaxial lines or waveguides These waveguides can be of simple, rectangular or circular shape, or more complicated, if they comprise steps which very significantly increase their bandwidth and reduce their impedance for the dominant mode TE 10 A coaxial line and a waveguide have

  of course different distributions of the electroma-

  Genetics To couple these two devices, it is therefore necessary to use a transition device which gradually modifies the field lines while adapting the impedances as well as possible. There are different transition devices, depending on the shape of the waveguide to be connected or depending on the width of the guide bandwidth, we can for example cite the transition device described in an article by

  M M TAKAKIYO NAKAGAMI, HIROYUKI YATSUKA, MASAYUKI

  ISHIZATKI published in FUJITSU SCIENTIFIC AND TECHNICAL

  JOURNAL of December 1978 and entitled: "Millimeter wave inte-

  grated circuits using alumina substrates "In this transition device between a waveguide with a single progressive step and a coaxial line, a substrate, on which is engraved a line with asymmetrical ribbons, called" microstrip line ", is pinched between the step progressive and the large opposite side of the waveguide This device is

  only applicable to single step waveguides.

  If the coaxial line to be connected is placed in a plane perpendicular to the axis of the waveguide, a so-called "perpendicular" transition device can be used, even in the case of a waveguide with double step However, such a device cannot be used in the case where the coaxial line is presented at the end by

relative to the axis of the waveguide.

  The object of the present invention is a transition device

  between a double step waveguide and a coaxial line at the end.

  The transition device between a double step waveguide and an end coaxial line, object of the present invention, in which a substrate, on each side of which a conductive tape is etched, is clamped between two shells forming a waveguide whose shape is similar to that of the guide to be connected and which are symmetrical with respect to the plane of symmetry passing between the steps of the latter, is characterized in that the two conductive strips, longitudinal with respect to the guide d waves, constitute, on the side of the coaxial line, a "microstrip" line in which the narrower strip is connected to the central conductor of the coaxial line and the other strip constitutes the ground plane and whose characteristic impedance is equal to that of the coaxial line, and on the side of the wave guide to be stepped to be connected, a two-wire line whose width is equal to that of the steps of the guide, means adapting the impedance of the "microstrip" line to that from there two-wire line. The present invention will be better understood on reading the

  detailed description given below with reference to the figures below

  attached which represent: Figure 1, a side sectional view of a transition device of the prior art; Figure 2, an embodiment of the transition device according to the invention; Figure 3, a top view, in section, of the device of Figure 2; Figure 4, a side view, in section, of the device of the

figure 2.

  FIG. 1 represents an example of a transition device of the prior art, between a waveguide with a single progressive step and a coaxial line at the end. This device comprises a substrate 1 on which is engraved a line "microstripl 2 connected to a from its ends to the coaxial line 3 The line 2 is pinched, at its other end, by a lug 4 disposed between the progressive step and the guide 6 The lug 4 exerts a certain pressure on the line

  microstrip 2 Its dimensions have been determined experimentally

  in order to minimize the standing wave rate at the entrance of the guide This transition device is used in the case of guides

of single step waves.

  FIG. 2 represents a perspective view of a transition device according to the invention between a coaxial line 19 and

a stepped waveguide 20.

  It comprises a waveguide of shape and dimensions analogous to those of the guide to be connected. It consists of two identical shells, upper 15 a (not shown) and lower 16 a, tightened face to face using the screws. ll Between these shells is pinched a substrate 12 -It then includes an adaptation section: formed by a waveguide, also consisting of two identical shells upper 15 b and lower 16 b, each being provided with a step, respectively 17 and 18 The shells 15 b and 16 b are tightened face to face by screws 11 and form, at their end which is not in contact with the shells 15 a / l Ga, an element of

  junction 21 for connecting the guide 20.

  Each face of the substrate 12 has a conductive tape,

  longitudinal with respect to the waveguides These two ribbons form

  ment, on the side of the 19% coaxial line, a "microstrip P 'line in which the narrower strip 13a is connected to the central conductor of line 19, the other strip 14a constituting the ground plane and being of width at least equal to three times that of the ribbon 13 a The characteristic impedance of the line 13 a / 14 a is equal to that of the coaxial line 19, i.e. 50 x for a line

classic coaxial.

  On the side of the waveguide 20 to be connected, the two conductive tapes carried by the substrate 12 form a two-wire line 13 b / 14 b whose width is equal to that of the steps 17 and 18 of the

  adaptation section 15 b / 16 b and that of the steps of the guide 20.

  The substrate 12 and the two-wire line 13 b / 14 b are pinched between the steps 17 and 18 over a length equal to half the wavelength 'mrn corresponding to the central frequency of the range of

  frequencies of the guide 20 Means 23 make it possible to adapt the impe

  dance of the "microstrip" line 13 a / 14 a to the impedance of the two-wire line 13 b / 14 b These means 23 can be an impedance transformer, progressive according to a certain law, formed by changing the width of the two conductive tapes from 13 a to 13 b and

  14 a to 14 b respectively The law used for adaptation progresses-

  sive impedance can be in Dolph-Tchebycheff for example, which has the advantage of maintaining the standing wave rate

  constant over the guide frequency band.

  Figure 3 is a top view of the device shown in

  Figure 2, the upper shells 15 a and 15 b having been removed.

  The substrate 12 is pinched between the shells 15 b (not shown

  felt) and 16 b and the two-wire line between the steps 17 (not

  shown) and 18 The width of the substrate 12 progressively decreases

  varnish over a length equal to a quarter of the average wavelength? m of the frequency band considered until it is equal to the width of the step 18 and the two-wire line 13 b / 14 b and, again over a length of m / 4 continues to decrease, together with the width of the two-wire line 13 b / 14 b, until it is equal to approximately lmm, this in order to progressively pass from one interval

  between steps filled with dielectric at an interval without dielectric.

  Figure 4 shows a side sectional view of the device according to the invention shown in Figure 2 The conductive tape

  13 a / 13 b is connected to the central conductor of the coaxial line 19.

  With the conductive plate 14 a / 14 b it forms on the side of the coaxial line 19 a "microstrip" line whose ground plane is 14 a and on the side of the waveguide 20, a two-wire line which is pinched between the two steps 17 and 18 of the shells 15 b / 16 b over a length of tm / 2 The two shells 15 b / 16 b form an adaptation section in which the height 24 between the steps 17 and 18 is equal to the thickness of the substrate 12 with two-wire line 13 b / 14 b, over a length of? to m / 2 then varies gradually so as to adapt the impedance of the adaptation section, at the end of the two-wire line 13 b / 14 b , to the impedance of the waveguide 20 in order to

  minimize the standing wave rate at the entrance thereof.

  The impedance adaptation in the 15 b / 16 b section can be by

example in Dolph-Tchebycheff.

  As an example to connect a 50 N coaxial line to a waveguide working in the X-Ku frequency band from 6.8 to

  18 G Hz, a substrate of dielectric constant ER = 2.2 and thick-

  0.8 mm seur ensures proper operation at 18 G Hz In this case, the tape 13 has a width of 2 e 3 mm at its end connected to the coaxial line 19 This gives the line "microstrip" I 13 a / 14 has a characteristic impedance of 50 X The transition device according to the invention has, among other advantages, a very easy assembly and

disassembly.

  There has been shown by way of example a transition device between a coaxial line and a rectangular waveguide with double step. However, the present invention is also applicable to

  circular waveguides with double step.

  The transition device, object of the present invention

  finds its main use in any microwave circuit.

Claims (7)

  1 Transition device between a double step waveguide and a coaxial line at the end, in which the substrate, on each side of which a conductive tape is etched, is pinched between two shells forming a waveguide whose shape is analogous to that of the guide to be connected and which are symmetrical with respect to the plane of symmetry passing between the steps of the latter, device characterized in that the two conductive strips, longitudinal with respect to the waveguide, constitute on the side of the coaxial line (19), a "microstrip" line (13 a / 14 a) in which the strip (13 a) is connected to the central conductor of the coaxial line (19) and the other   ribbon (14 a) constitutes the ground plane and whose characteristic impedance   ristic is equal to that of the coaxial line, and on the side of the stepped waveguide (20) to be connected, a two-wire line (13 b / 14 b) whose width is equal to that of the steps of the guide (20) , means (23) adapting the impedance of the "microstrip" line (13 a / 14 a) to that of the two-wire line (13 b / 114 b).   2 transition device according to claim 1, characterized in that the end of the two-wire line (13 b / 14 b) and of the substrate (12) on which it is engraved are pinched between the steps (17 and 18) of an adaptation waveguide, also formed of two identical shells (15 b / 16 b) in which the width of the steps (17 and 18) is equal to those of the steps of the guide (20) and in which the height between the steps (17 and 18) is equal to the thickness of the substrate (12) over a length equal to half the average wavelength λ m corresponding to the central frequency of the frequency band of the waveguide ( 20) then varies until reaching the   height between steps of the guide (20).   3 transition device according to claim 2, characterized in that the two-wire line (13 b / 14 b) and the substrate (12) are pinched, over a length equal to half the average wavelength m in the band of frequency considered, between the steps (17 and   18) of the adaptation waveguide (15 b / 16 b).   4 Transition device according to claim 3, characterized in that the width of the substrate (12) decreases progressively over a length m / 4 until it reaches the width of the two-wire line (13 b / 14 b) and continues to decrease gradually , together with the width of the two-wire line (13 b / 14 b) over a length of m / 4 / o Transition device according to claim 1, characterized in that the adaptation means (23) consist of a progressive impedance transformer according to a certain law and formed by varying the width of the two conductive tapes (13 a at 13 b and 14 a at 14 b).   6 Transition device according to claim 5, characterized   in that the impedance of the "microstrip" line (13 a / 14 a) changes.   according to a law in Dolph-Tchebycheff until being equal to that of the two-wire line (13 b / 14 b).   7 o Transition device according to claim 2, characterized in that the variation in height (24) between the steps (17 and 18) is such that the impedance of the guide & adaptation waves (15 b / 16 b), at the end of the two-wire line (13 b / 14 b)> evolves according to a certain law until it is equal to that of the waveguide (20) o 8 Transition device according to claim 7, characterized in that the impedance of the adaptation guide (15 b / 16 b) follows a law in Dolph-Tchebycheff   9 Connection microwave circuit including a provision   transition sitive according to any one of the preceding claims. teeth.