DE1014183B - Microwave receiver consisting of HF and NF parts - Google Patents

Description

Microwave receiver consisting of HF and LF parts. The invention relates to high-frequency receiving arrangements, in particular to receivers with HF and LF parts, preferably on microwave receivers, which are used in both HF and are also built in the NF part like a printed circuit.

Known microwave receivers require particularly for the HF part extensive and extensive circuit elements such. B. Waveguide, special Frequency mixers or other components commonly known as "microwave interconnect components" designated.

With the increasing technical development in microwave receiver technology, such as B. with shortwave receivers, radar, direction finding arrangements and aeronautical radio navigation systems, have become the requirements for a greater amount of such apparatus and in particular to smaller dimensions and lighter weight of the microwave equipment greater.

One of the objects of the invention is to provide a microwave receiver to create that not only has smaller dimensions, but also relatively simple, compact, considerably lighter in weight and not the usual Having microwave connection components. At the same time, an improved HF part should be created for converting the RF or microwave signals into signals of low frequency will.

According to another feature of the invention there is provided a microwave receiver specified, which is built according to new principles for the chassis and component arrangements is. According to a further feature, these arrangements are particularly advantageous using printed circuit type technology for both RF and also manufactured NF parts.

A characteristic of the invention consists in the application of a basic principle for a theoretically completely parallel transmission line system. If a parallel pipeline system could be constructed in such a way that its electric and magnetic fields largely remain the same along the ladder regardless of minor inaccuracies in shape and size and relative spacing of the conductors, as you would z. B. by use identical conductor can reach a certain distance, so would a minimum Radiation losses occur. Such theoretically completely parallel conductor systems however, cannot be produced in practice. The invention now uses the chassis even as the first or "earth conductor", the second or "line conductor" in the desired Form or as a circuit on a thin sheet of dielectric material and As a result, the line conductor at a close, largely parallel distance to the plane Surface of the earth conductor.

There are now unbalanced ribbon cables for the decimeter wave technology known. The cross section of these line arrangements is so large that this Arrangements are self-supporting and not on the type of printed circuit technology can be produced. On the other hand, it is also known per se for radio sets already used printed circuit technology for certain items of decimeter wave receiving arrangements through special training of these items to use. For example, it is known to use printed circuit technology for to apply the decimeter technique by designing the decile line as a ribbon line or coupling or energy distribution circuits in the form of ring conductors with branches (so-called “hybrid couplers”) or parallel ribbon cables will. These strip-shaped line conductors run in these arrangements but between two other wider conductor surfaces. Such an arrangement was kept to achieve the desired mode of propagation of the waves - based on the Coaxial conductor technology - when using printed circuit technology on microwaves -Recipient or parts for required. In contrast, the invention creates an advance and used in a certain way only from a line conductor and an earth conductor Existing strip conductors also for the production of printed circuit technology manufactured microwave receiving arrangements and creates a complete microwave receiver, in which all parts of the circuit from the microwave receiver input to the LF output stages in the same printing process with special use of the earth conductor of the microwave input part for the NS stages can be produced and only a single cover plate is required, which is in one piece, in particular contiguous piece that can be printed.

If the earth conductor is made considerably wider than the line conductor, in this way a mirror effect is achieved in which an electric and magnetic field distribution between the two conductors is reached, which is largely considered to be the same as between a conductor and the neutral plane of a two-conductor parallel system can. The so-called earth conductor can theoretically extend to infinity Have width. In practice, however, a slightly larger width than that of the is sufficient Conductor that is so large that it has an ample concentration of the electrical Field caused between the associated surfaces of the two conductors. The width however, the earth conductor can also be considerably larger than that of the line conductor be and can have a conductor surface as a common flat conductor surface can be related to different circles, which of line conductors in be formed a small distance and run largely parallel to it. The diameter or the width of the conductor and the distance between the conductor and the flat conductor surface determines the characteristic impedance of the (asymmetrical) ribbon cable. The distance is preferably a fraction of 1/4 wavelength of the operating frequency, and the spacing is usually smaller than the width of the line conductor.

Using one or more walls of the chassis as a ground conductor and by using a sheet or plate of dielectric material both the circles of the HF part and the LF part of a microwave receiver in the manner of the technology known from printed circuits with such a technology Assignment. The chassis wall can also serve as a ground or ground as well as a carrier of circuit components such as tubes, crystals, capacitors, resistors, Coils, etc. Bring the circles on one side of the flat conductor and the Components on the other side, the flat conductor acts as a shield. at The ground conductor part of the chassis can be omitted from the NF part, so that a Circular layout can be attached on both sides of the dielectric plate.

The invention is explained in more detail with reference to the drawing, which represents an exemplary embodiment. Fig. 1 is a plan view showing the construction of the microwave receiver, with certain parts being shown in block diagram; Figure 2 is a bottom view of the receiver shown in Figure 1; Fig. 3 is a view in section along the line III-III of Fig. 1 showing the structure of the arrangement for the microwave input signals, a crystal detector structure and. the coupling transformer to the IF part; FIG. 4 is a view in section along the line IV-IV shown in FIG. 1 and shows the structure of an oscillator of the klystron type; Fig. 5 is a sectional view according to line VV shown in Fig. 1 and shows the arrangement of a cavity resonator; Fig. 6 is a sectional view taken along the line VI-VI shown in Fig. 1 and showing a short-circuit connection between a line conductor and the ground conductor; 7 is a top view of the HF and LF parts of the chassis according to another embodiment. In FIG. 1, the chassis 1 of a microwave receiver comprises a conductor surface 2 and a support or plate 3 made of dielectric material which is assigned to the surface of the conductor surface 2. The conductor surface 2 acts as a common ground conductor for the HF part 4 and the IF part 5 and for each other LF circuit, such as. B. audio frequency part that can be mounted on the chassis 1. According to the exemplary embodiment, the RF part 4 comprises three coupling or distribution and mixing circuits A, B, C, each of which contains four branch lines, e.g. B. l a, 2 a, 3 a and 4a for the circuit A. The branch lines of the circuits B, C are constructed similarly and for the circuit B with 1 b, 2b, 3 b and 4 b and for the circuit C with 1 c, 2c, 3c and 4c.

In the case of the HF part 4, the branch conductors are interconnected by a ring conductor 6. The first and fourth branch conductors 1a and 4a. are at opposite points switched on, approximately at a distance of 3/4 wavelength, while the conductors 2 a and 3 a are connected to the ring conductor at points that are .l / 3 and 2/3 A or .1 / 4 and A, / 2 are removed from the connection points of the lines la and 4a. These distances can, of course, be larger by an integer multiple of wavelengths, or each of the two bends between the branch lines can be 1/2 wavelength to be taller. These branch conductors are arranged in a plane that is essentially runs parallel to the plane of the conductor 2, and thereby act for the RF signals like the well-known coaxial ring-shaped Magic-T-coupler, 7r. For example, shares a signal wave applied to the branch l a, at the junction of the ring-shaped Head and flows from there in phase from junction 2a and 4a, however not from junction 3a, from where signal energy in opposite directions flows along the annular conductor 6 out of phase by 180 °.

The current flowing via the arm 3 a to the connection point with the ring-shaped conductor 6 is divided in a manner similar to I between the arms 2 a and 4 a, with the exception of the junction 1 a. Of course, other forms of conductor loops can also be used which meet the requirements of an asymmetrical ribbon cable, e.g. B. those according to the embodiment of FIG. 7.

To avoid reflections from the ends of the branch conductors of the ring conductor avoid are those junctions that flow freely with a limited Provided surface piece which runs parallel to the flat conductor surface 2 and Tuning elements with susceptibility value for adapting the associated input coupling or has crystal branches at the characteristic impedance of the transmission line, that formed by the branch line and the adjacent flat surface of the conductor 2 will. Such end pieces are for the branch lines 1 a, 2 a and 4 ä with 7, 8 and 9 designated. It can also be arider ", u @, Types or forms be used by adapting end pieces, such as B. one associated with the branch line Adjustment piece made of resistance material like the one labeled 10 is, can be carried out, which around the articulation 11 with respect to the line 3 a is adjustable. It can also be used a short-circuit piece that is appropriately attached to the joint to be adapted.

As can be seen from FIGS. 1, 2 and 3, a is attached to the mixer A applied microwave signal is received by the antenna 12 and via the coaxial line 13 passed to the branch conductor 1 a. The outer conductor 14 is with the help of a connecting sleeve 15 connected to the underside of the chassis line 2 (Fig. 3). The inner conductor 16 is similarly connected to the branch conductor 1 a with the aid of the conductor 17, which passes through an opening 18 of the conductor 2. The one over the coaxial line 13 incident microwave energy is along the branch line between the branch conductor and the associated area of the conductor 2 in TEM mode. The on this Wise received energy is between the branch lines 2 a and 4 a, to which the crystal detectors 19 and 20 are coupled, divided.

3 shows the coupling arrangement for the crystal detector 20, which is fitted in a dielectric sleeve 21, which in turn is arranged in a connecting sleeve 22 connected to the rear of the conductor surface 2. The conductor 2 is also provided with an opening 23 through which a connection 24 connects the line conductor of the branch line 4ca to the crystal 20. The output of the crystal is connected via the conductor 25 to the coupling coil 26, which is connected via the resistor 27 to a ground connection 28 present on the conductor surface 2 (FIG. 1, partly also shown in FIG. 3). The ground connections in the circles A, B and C can be designed as a direct current return line for the crystals and can be connected to the end terminals of one of the branch conductors, such as. B. 48 (Fig. 1, circle C) be attached. Furthermore, an HF bypass capacitor 29 is connected between coil 26 and conductor 2. The output of the crystal conductor 19 is similarly connected with the aid of the conductor 30 to the coil 31 which is connected to the earth conductor 2 via the resistor 32 and capacitor 33.

With the coils 26 and 31 (Fig. 1 and 2) are connected in parallel Coils 34 and 35 coupled, one end of which is connected to ground by conductor 36 is, while the other to the control grid of the first stage 37 of the IF part 5 is connected as shown by conductor 38. The IF part can consist of several There are stages, the tubes of which on the chassis 1 essentially with the help of holding parts, held by the ground conductor 2 are attached. The tube 37 is a miniature or subminiature tube held by brackets 39. Of course you can also larger tubes both in the IF, NF or output section on the chassis 1 with the help be arranged known base. The conductor 2 can also be omitted in the NF or IF section will. The output of the IF part 5 is connected to a limiter 40 in a known manner, which in turn is applied to a discriminator 41 to which an image frequency amplifier stage is attached 42 connects, all of which can be supported by adjacent chassis walls.

The local oscillator 43, its frequency with the input frequency the microwaves is mixed, is, as can be seen from Fig.1, 2 and 4, on the Earth conductor mounted. The oscillator shown is a kly stron, but it can any other RF oscillator can of course also be used. The output of the oscillator 43 has a coaxial connector 44 which is connected to a further coaxial connector 45 is connected, and the outer conductor .des connector is directly with connected to the earth conductor 2, while the inner conductor 46 is connected through an opening in the line conductor to the line conductor of junction 3 b protrudes. The one generated by the oscillator 43 Voltage arrives at the branch 3 b of the circle B, in which the waves on the Split branches 2 b and 4 b. The portion that flows through the branch 4 b is accordingly the setting of the damping part 10 and damped to the mixing circuit A via the Branch 3 a, where it connects to branch 2 a and 4a. distributed. The waves from the oscillator mix with the signal waves, which also move on arms 2a and 4a. distribute and get to the crystal detectors 19 and 20. As already described, the outputs of the crystal detectors are connected to the IF section 5 connected.

The oscillator 43 is provided with an LF control loop that controls the circuits B and C includes. These two circles are with the help of the two branches 2 b and 1 c connected, the connection 1 c being provided with an attenuator 47 is. The circle 2c is connected to the earth conductor by a shorting clip 48 (FIGS. 1 and 6) tied together. The branch line 4c is connected to the cavity resonator 49, which consists of a housing 50 (Fig. 5), which through an opening 51 with which .The conductor 2 is provided, couples, the conductors 2 and 4c at a distance from one another are arranged and the microwaves, which run along the branch 4 c, with the Resonator 49 are coupled. The resonator can still be equipped with an adjustable tuning probe 52 be provided. The branch line 3 c is connected to a crystal detector 53 in the same Way as the crystal 20 of Figure 3 is connected to the corresponding line. The branch line 1 b of the circle B is also connected to the crystal detector 54 connected in a similar way to the crystal 20. A LF amplifier 55 with symmetrical Input is connected to the outputs of crystals 53 and 54. The exit the amplifier 55 is connected to a suitable electrode of the oscillator 43, to stabilize the frequencies.

With regard to the LF control circuit, the currents from the oscillator 43 in circuit B are divided between branches 2 b and 4 b. The portion of the oscillator energy reaching branch 2 b is partially damped with the aid of slide 47 and applied via branch 1 c to ring conductor C, which distributes the energy to branches 2 c and 4 c. Partial reflections from the cavity resonator 49 and short-circuit clip 48 are in phase with respect to the connections of the branches 1 c and 3 c. The branch line 3 c conducts the reflected energy to the crystal detector 53, from where the electrical waves reach a frequency comparator or rectifier arrangement with amplifier 55; the energy reflected via branch 1c flows via attenuator 47 to or branch line 2b of circle B, where it is divided between arms 1b and 3b. The portion that flows to branch 1 b is applied to crystal detector 54 and, after detection, to the other input terminal of amplifier 55. Each change in frequency of the oscillator 43 causes a corresponding change in the output of the amplifier 55, which in turn supplies the bias voltage for an electrode of the oscillator and thereby effects the frequency stabilization of the oscillator.

It will be readily understood that the distribution and mixing circuits A, B and C can be manufactured in the simplest and cheapest manner compared with those made up of rectangular waveguides or those of the coaxial type, and that the printed circuit type manufacture is easy to carry out so that a chassis wall can be used as the conductor surface that forms part of the transmission circuit and that various circular components such as crystal holders, oscillators, cavity resonators, tubes, resistors, capacitors and coils on the conductor surface on the opposite of the distribution and mixing circuits Side can be attached and that the conductor surface in this way serves as a screen between the circle and the associated components and that the couplings between these components and the circular arrangements can easily be achieved directly through the conductor surface. The same ground conductor can serve as a carrier and current conductor for the components of the IF part and LF part and, if necessary, also form the carrier for other circular units, such as parts of both the HF part and the LF part. In the embodiment according to FIGS. 1 and 2, the parts of the ZF or hTF part are shown as conventional wire connections. However, the IF circles or the other associated circles can also be applied to the dielectric layer 3 in a similar manner to the circles A, B, C in the manner of printed circuit technology.

In Fig. 7, another embodiment is shown in which both the HF and the NF parts on the common chassis in accordance with the invention Way are applied. The chassis 56 comprises a plate of dielectric material 57, which has a layer 58 of conductive material on one side that forms the RF part covered. Parts of the conductive layer 58 can also run up to the NF part, such as B. the common connecting conductor 59 and the associated in Figure 7 dashed represented circles. A preferably applicable version of the printed type Circuit technology consists in .that both sides of a dielectric strip be covered with layers of conductive material, such as. B. copper, and here The desired circles, bus bars and conductor surfaces are printed on the conductor layers will. During the printing process, a material can be applied that makes up the conductor parts from the etching bath to which the chassis is subjected. The parts which are not covered with the material, are etched away and leave the desired Circular components such as busbar strips, coils, connecting circles or flat Pieces of ladder back. The protective layer is then removed, leaving the desired Circle components remain.

The HF part 56a (Fig. 7) is provided with a conductive layer, which forms a conductor surface, the one applied to the dielectric layer Line conductors are assigned and form the HF transmission path. The ladder surface 58 is attached according to the embodiment under the entire HF part 56 a. This is not absolutely necessary. There is an advantage to such an arrangement however, that for the HF part and the one on the side of the conductor surface of the chassis attached circular components an effective shielding is created. The conductor layer however, it also serves as a conductor for power distribution. The illustrated RF circuit arrangement comprises two strip conductors 60 and 61. The two strips are arranged. that they form a mixed coupling, whereby incoming RF signals with the output a local oscillator 62 and to a crystal detector 63 can be applied, which supplies the IF frequency that is sent to the NF part 56 b is created. The connector 64 is a coaxial coupler and is used for coupling to the coaxial line 65 of an antenna and is similar to the antenna coupling 15 of Fig. 3 formed. The crystal 63 is also connected to the line 60 connected in a similar way as in Fig.3 (part 22). Behind the connection points 63 and 64 wind the line 60 closed by two conductor surface pieces 66 and 67, which have a capacitive susceptance to match the impedance of the neighboring connections represent.

The connection of the local oscillator 62 to the line 61 is the same as in FIG. 4. The susceptance 68 is expanded by a flat one Leakage of the line 61 is formed and serves to match the impedance of the junction to the local oscillator 62. The line 61 has a portion 69 which parallel over a length of half a wavelength or a multiple thereof runs to the line 60 and operates as a directional coupler, according to the Embodiment as a mixed coupler. The other end of the line 61 is on the Junction 62 'is completed with a load 70.

During practical operation of the HF part 56a, the incident RF signals over the coaxial line 65 to the through line 60 and the associated Surface of the conductor surface 58 formed transmission line applied. The exit The local oscillator is on the transmission line running through the strip 61 and the associated conductor surface 58 is formed, connected. The two waves are mixed in the directional coupler part of the circuit arrangement and the mixed product distributed over the load 70 and the crystal 63. The crystal 63 detects the Waves of low frequency for transmission to the IF stages of the hTF part 56 b.

The partially shown NF part 56 b consists of conductor sections according to the type of printed circuit that comes along with the printed RF parts are arranged in a common chassis. The output terminal 71 of the crystal 63 is connected to the center of a printed coil 72, its outer turn 73 runs parallel to a likewise printed coil 74, as well as with a capacitor 75, the other end of which is connected to ground. The coil 74 is across a working capacitor 76 connected to ground, and a display device 77 is for displaying the through the crystal flowing current is switched via the capacitance 76. With the coil 72, a variable capacitor 78 is also connected together.

The fixed capacitors 75 and 76 are turned from two to opposite Sides of the dielectric layer 57 printed plates 79 and 80 are formed. In In the same way, the variable capacitor 78 is made up of two capacitor plates 81 and 82, the overlap of which is adjustable by a linkage 83 of the plate 81 is.

One end of the line conductor 84 is connected to the crystal lead 71 and connected at the other end to the grid 85 of a pentode 101. the Pentode is preferably supported by a suitable socket attached to the chassis carried. It can, if necessary miniature tubes, similar Ways as shown in Figs. 1, 2 and 3 can be used, and others as well suitable bases are used.

The cathode has the usual heating element 86 to which the power lines 87 and 88 printed on the dielectric layer 57 are. A bias circuit is connected to the cathode, which consists of the resistor 89 and the capacitor 90 consists. The resistor 89 is made of resistor material, which is formed by a method known for printed circuits. The anode 91 is connected to a transformer via a printed line 92, which consists of a primary coil 93 and a secondary coil 94. The two coils are deposited on opposite sides of the dielectric layer 57. That the other end of the primary coil is across conductor 95 and capacitor 96 as well a choke coil 97 connected to a printed bus 98 which is connected to the Potential B is applied. The secondary coil 94 is at one end 99 to the manifold 59 connected and with the other end 100 to the control grid of a pentode 102 of the next IF stage.

The rest of the NF part 56 b is "printed" in a similar way like the first two ZF stages and is, as can be easily understood from the drawing is trained. According to the invention, as FIG. 7 shows, a common chassis used for HF and LF = reil. Of course, this ordering can take many forms be modified. So z. B. the HF circuit can be much more extensive than according to 7, like FIG. 1, is just one of many examples of printed RF circles is. In the same way, the distribution and mixing circuits can be used in many ways be modified.

The exemplary embodiments described are therefore not intended to be a restriction mean to the cases shown, but only serve for explanation.

Claims (7)

PATENT CLAIMS: 1. Microwave input section, HF and mixing section as well as IF and LF section plus output stage (in particular with limiter, discriminator and output section) having a microwave receiver, preferably constructed in the manner of a printed circuit, with a dielectric base plate on both sides Conductive parts are attached, characterized in that the base plate (3) in the area of the HF part (4) has a layer (2) forming a conductor surface on one side and, on the other side, parallel to the conductor surface, preferably at a close distance from it and has conductive circular elements (A, B, C) which form a parallel conductor system for the HF signals. 2. Receiver according to claim 1, characterized in that that at least a part of the conductive layer (2) extends beyond the HF part up to to the area of the preferably on both sides of the dielectric layer (3) arranged NF part together with output stage (40 to 42) and for parts of this forms a common busbar in other areas. 3. Receiver according to one of the preceding claims, characterized in that the RF or. Mixing part (4) has a directional coupling arrangement provided with two input conductors (1 a, 3 a.) And output conductors (2 a, 4 a), in particular a closed conductor loop, preferably a first ring conductor (6), that furthermore conductive connections (13, 16) for applying an RF signal to one of the input conductors (1 a) and the local oscillator (43) is connected to the other RF input conductor (3a) via conductive connections (4 b), a detector or more detectors, preferably crystal detectors (19, 20) are connected to the output conductor (2a, 4a) via further conductive connections and that the LF part (40 to 42) has an electron tube arrangement connected to the conductor surface and conductive connections for connecting the output conductor to this electron tube arrangement. 4. Receiver according to claim 3, characterized in that four branches (1a, 2a, 3a , 4a) of the first Richtkopplungsanordnun.g, preferably ring conductor (6), are arranged at such a distance that a first branch (1 a) supplied waves, in particular the input signal over the second (2a) and fourth (4a) branch, with the exception of the third branch (3a), and that incoming waves, in particular the oscillator (43) via this third branch (3a) the second (2a) and fourth (4a) branches are divided with the exception of the first branch (la). 5. Receiver according to claim 4, characterized in that that the first (64, Fig. 7) and fourth branch (to 63) or connection a first Line conductor (60) and the second (62 ') and third branch (to 62) through a second line conductor (69) are connected together and the first and second line conductors (60, 69) for a length (69) x of about half a wavelength or a multiple of which run parallel and that the second branch (62 ') has an end load (70) and the fourth branch (63) is coupled to a crystal detector. 6. Receiver according to claim 4, characterized in that the oscillator (43) connected to the third junction (3a, Fig. 1) of the first directional coupling arrangement, preferably the first ring conductor (6) via a conductive connection (3a), has a second directional coupling arrangement ( B), preferably in the form of a second ring conductor with four branches (1 b, 2 b, 3 b, 4 b) , the fourth branch (4 b) of which is conductively connected to the third branch (3 a) of the first directional coupler arrangement, while the third branch (3b) of the second directional coupling arrangement (B) is connected to the oscillator (43). 7. Receiver according to one of the preceding claims with arrangements for automatic frequency control, characterized by a third ring conductor (C) with four branches (1c, 2c, 3c, 4c), the first branch (1c) of which with the second branch (2b) of the second ring conductor or directional coupler (B) and its fourth branch (4c) is connected to a cavity resonator (49), that furthermore the second branch (2c) of the third ring conductor (C) is short-circuited with the conductor surface and connections of the first branch (1 b) of the second ring conductor (B) and the third branch (3 c) of the third ring conductor (C) with a frequency rectification arrangement with amplifier (55) for obtaining a control voltage obtained by comparison and amplification thereof are present. B. Receiver according to one of the preceding claims, characterized in that at least one of the branch conductors (1d) of the ring conductor (ä) has tuning elements (7) having susceptibility values for balancing the impedance mismatches caused by the antenna couplings attached to the RF lines. 9. Receiver according to one of the preceding claims, characterized in that the conductive layer (2) or the conductor surface is formed by a wall or chassis of the receiver. References considered: U.S. Patent No. 2,474,988; Electronics, June 1952, pp. 114 to 118.