DE932025C - High-frequency network for the frequency-dependent coupling of two switching parts - Google Patents

Description

There are already high-frequency networks for the frequency-dependent coupling of two Sehialtteile became known that a closed sliding conductor with two terminals on non-coincident Use positions in such a way that two adjacent, in Lead current paths dimensioned according to their length.

These networks' can be used as sieve circles for certain frequencies, for phase shifting and for setting an impedance through suitable dimensioning and shaping of the individual Network members serve.

According to the invention, frequency-dependent coupling is used in a high-frequency network two switching parts with a closed Sdhl'eifenleitar with two terminals on not coincident places an additional impedance element is provided, which is connected to one of the side by side Head of the network to a suitable one between the terminals Body is connected. This allows the properties of the network in the desired Way to be changed.

This added impedance at one point in a network can have a closed loop effect for

supply other frequencies than for which the network itself is effective. The network can also be adjusted by means of a variable impedance connected to it.
The invention is based on the drawings

. . explained in more detail in several useful embodiments.

In Fig. Ι ιοί represents a high frequency source, 103 a consumer that is connected to the power source via the transmission line 105. The network 106 is connected at a suitable point on the transmission line 105! It consists of the three branches 107, 108, 109, the form a closed loop with each other. Branch 107 consists of, a partition of the excess, transmission line 105. An additional impedance 111 is connected to this network at 110, which can consist of an open transmission line. The branches 108 and 109 are with the Transmission line 105 and branch 107 connected to points 113 and 115. The branches 107, 108 and 109 together form a network represents, which with suitable dimerization as a wave filter or as an arrangement for modification the transmission properties is used. However, a network is now proposed that is precisely matched can be to have a sieve circle effect or to achieve an impedance transformation without affecting the branches with respect to the frequency be measured exactly. This is indicated by an impedance (e.g. the open transmission line 11 r) which is connected to the network lead at a suitable point.

Let branches 107, 108 and 109 of the mach series be labeled Q ₂ , Q ₁ and Q _3. Here, Q means the length of the various branches, expressed in wavelengths. The length of the open transmission line -i 11 is denoted by / and! also expressed in wavelengths. It can be proved mathematically that regardless of the dimensioning of this network. H. of the values Q ₁ , Q ₂ or Q ₃ , it is possible to determine the length / of the open line section 111 in such a way that the network blocks for a given frequency.

This value of I results from the following formula

λ ~ sin Q ₁ · sin Θ ₃

where 2 is the wavelength of the transmitted energy.

The validity of this formula has been experimental established.

For example, let Q ₂ = 152.4 cm = 26.9 ° at 14.71 MHz and Q ₁ = Q ₃ = 228.6 cm = 40.35 ° at the same frequency. Substituting these values into the equations gives

= 73 = 7 °

in order to

= 0.205;

^ T 73 = 7 and thus -i

since λ is approximately equal to 20 m, / = 4.18 m.

When in a practical case you can wire

No. 6 is used, which is spread to 30.5 cm, the result must be changed for normal end insulators 12.2 cm should be corrected to account for the influence of the end. So you get / = 4.05 m; with this dimensioning of / the whole arrangement as a filter for 14.71 MHz. This result was made through the experiment within normal accuracy limits confirmed.

In the equation, if Q ₁ + Q ₂ + Q ₃ = 360 ⁰ , then! the sine in the numerator becomes zero; likewise the cosine vanishes for Q ₁ + Q ₃ - Q ₂ = i8o °. / becomes zero when the sum of the three branches = 360 ° or when the sum and difference of the branches = 180 °. However, if Q ₁ or Q _{3 is} equal to zero or a multiple of 180 °, then the denominator disappears and! characterized the solution of the equation is indeterminate. In this case, the impedance of any size may be connected to the m. the point i 10, without exerting any influence on the Filiterwirkung the network.

Since, under the above conditions, any large impedances can be connected to the network can without disturbing the blocking effect, the appended I ^ itungSiStücfc 111 according to the equation so be determined that a blocking effect is generated for any second frequency.

If, for example, f is the frequency for which the network Q ₁ , Q ₂ , Q ₃ forms a complete blocking circuit and if f _{2 is} another frequency that should also be blocked, then according to the equation, after Q ₁ , Q ₂ , Q _{3 are expressed} in wavelengths of frequency f ₂ , a value of / with which the desired effect is obtained. In this case you get a filter that blocks two different frequencies exactly. If you use a closed line instead of the open line, you only need an amount of 90 °, expressed in wavelengths:, from the calculated / subtracted or added for the open line. Such a network is shown in FIG. For a location in the line 111 is equal to / + -is a short-circuit wire 217 superiors ^{$ 10}

see, so that a closed line is created. The short term war represents an end to which is equivalent to a transmission line the length of a quarter wavelength, the network can be grounded at this point, so that other frequencies imposed on the line are grounded.

In Figs. 1 and 2 networks are shown in the shape of a triangle, while the impedances the shape of open or closed pipe sections form. Since the impedance can also be realized in another way, an inductance 311 (Fig. 3) can be used instead of the line section, which must be shaped and adjusted so that it achieves the same effect as the open or closed Leituingsabschnitt. In general, any suitable form of impedance is capable of that Replace transmission line as long as it remains Effect is present.

In Figure 4 the network is in the form of two

Semicircles connected to the transmission line. In this case, branches 408 and 409 are dimensioned with respect to point 410 in the same way as in the arrangements of FIG. The particular shape and nature of the networks is immaterial, because it is only necessary that the various branches are correctly dimensioned in relation to one another. In all cases the lengths Q ₁ , Q ₂ and Θ _{3 must} be measured along the lines that make up the various arms.

In Fig. 5, a capacitor 519 is in place

510 in place of the impedance shown in the previous figures.

When Q ₁ + Q _s + Q _{2 is} approximately equal to 360 ⁰ and

Q ₁ and Q _{3 are} neither equal to 180 ° nor equal to zero ¹ , then the right-hand side of the equation for / becomes very small. In addition, when Q ₁ + Q ₃ + Q ₂ differs very little from 360 ⁰ while

COS

- is positive, then will

21!

extremely small and positive, so that the length of the open section of conduit extending at point 510 connected, is, also, is small. That means, that the network meets the conditions for exact trap circuit effect by connecting a small Capacity at point 510 can be adjusted e.g. B. by a capacitor 519. This capacitor is expediently designed to be adjustable in order to close the frequency blocked by the network or to tune the network to block a fixed frequency. Such capacitors turn out to be beneficial as it is easier to set a capacitor than the length to change the transmission line, with which an exact setting may be difficult power.

Fig. 6 shows an application of this principle to the concentric transmission line 605, to which a network is connected at points 613 and 615, which is also designed as a concentric transmission line. This loop should fulfill the relationship Q ₁ + Q ₂ + Θ ₃ = 36o ° as precisely as possible. In the event of a small error, a capacitor plate 621 can be used to compensate for this, which is connected to the outer concentric conductor and can be adjusted with respect to the inner conductor, for example by means of a wing hood 623, in order to change the capacitance and thus achieve an exact blocking effect. This device facilitates the setting of the filter circuit. This method is particularly advantageous for concentric cables, as it is very difficult to change the connections at points such as 613 and 615 in order to achieve the desired setting without additional impedance.

The easy adjustability has proven to be very useful for networks according to FIG. 6, which are used for Stabilization or frequency control of an ultrashort wave oscillator should be used. In this case, the concentric cable must be kept ■ at a constant temperature.

Up to now fet d'fle mode of operation of the network has been described as a sieve circle. Use for other purposes is discussed below.

In FIG. 7, a high frequency source 1201 is connected to the transmission line 1202 is finished durc'h the load resistance ¹ 1203rd The line is bridged by the composite network 1204, which consists of the network A B, C, A and the additional separation principle CD of length /. If AC is chosen to be equal to CB , various influences can be exerted on the distribution of the standing waves by adjusting the length of the line CD. AB corresponds to Q ₂ , AC is equal to Q ₁ and CB is equal to Q ₃ .

Tests in which AC was equal to CD and ACB for different dimensions, expressed in wavelengths, resulted in CD values of the maxima and minima of the standing waves for different lengths. Measurements were also taken with regard to the distance h that the minimum of the standing waves has from the connection point of the network. Measurements were made for three different dimensions of the network.

1. ACB = 0.153 and AB = 0.98 wavelengths

2. ACB = 0.153 and AB = 0.056 - go

3. ACB = 0.112 and AB = 0.056

The curves in Figs. 8 and 9 show the results again. The curves of FIG. 8 represent the ratio Q of the maximum to the minimum of the standing wave, which is plotted as a function of the length / added impedance, which is given in wavelengths. These curves show that Q is not only dependent on /, but that for every composite network there is a point for which Q equals 1. That is a particular advantage of this network.

In Fig. 9, curves 1, 2 and 3 represent the distance h (distance of the minima of the standing wave from the network, expressed in wavelengths) as a function of the length /, expressed in wavelengths. It turns out that Ji depends on the setting of the short circuit wire D and on changes in the dimensions of the network itself. According to the inversion law of high-frequency networks, a network that can produce standing waves on a line terminated with the wave impedance must also be able to adapt a line with standing waves. If, for example, a ratio Q is equal to 2, a network for impedance matching can be specified in implementation of the inventive concept in such a way that one of the curves 1, 2 or 3 in FIG. 8 or 9 results. The length / is obtained from FIG. 8 and the corresponding value h from FIG. 9. It is then only necessary to measure the distribution of the standing waves in a line and to place the network at a point whose distance from the minimum is determined by the curves in FIG. Then a suitable length / according to the curves of FIG. 8 is attached.

Nevertheless, only three curves in FIGS. 8 and 9

are given for three different dimensions of the network, understandably result - smooth curves also · for other dimensions of the network. Hence an adjustment is obtained the transmission line also for other types of network. When connecting the adaptation r · and The filter effect, which was previously described, can be applied to different frequencies at the same time

ίο Achieve impedance matching and filter effect.

In Fig. 10 is such a system for impedance matching shown. 701 is the high frequency source, 702 the consumer. In the transmission line 705 lies the network 706, which was determined in the manner described above. The input impedance of network 706 at point 713 becomes equal to the characteristic impedance of the transmission line 705 in this case. Since the network is in the right place according to the curves of FIG. 9, arise on the part of the transmission line, lying to the left of network 706 are not standing waves. 711 is an attached open Leituingsistücfc.

Several such impedance analyzes can be inserted into a transmission line in order to determine its impedances properly, and use any desired combination of such networks to create a to obtain the desired composite result.

In Fig. 11, a double filter circuit is shown. 901 is a radio frequency source (e.g. a receiving antenna) and 902 is a consumer (receiver). The receiving circuit 901, 902 can in the The proximity of two transmitters 900, 903 is arranged work with other frequencies than are received.

With this arrangement the interception frequencies can be disturbed by the strong signals of the two neighboring transmitters. In this case, a filter effect for multiple frequencies is expediently used. For the frequency ^ ₁ and the frequencies f ₂ and f _{3 of} the two neighboring transmitters, the frequency filter 904 can be designed in such a way that mainly the frequencies / ₂ and / _{3 are} blocked.

12 shows an application of the double filter circle effect in an antenna system in which a single antenna 1001 emits two frequencies f ₂ and f _{3 of} the transmitters 1002 and 1003 and at the same time feeds received signals of the frequency ^ _{1 to} a receiver 1004. In this case the filters 1012, 1013 and 1014 are assigned to the arrangements 1002, 1003 and 1004. Filter 1012 is balanced so that the frequencies f _t and / _{3 are} blocked, while there is no noticeable resistance _{for / 2.} Filter 1013 should block the frequencies f _± and / ₂ and let f _s pass, while! Filter 1014 should block the frequencies / ^ and / ₃ and let the frequency Z ₁ pass. In this way you can work with three different frequencies on a single antenna without causing overlap in the individual circles.

Instead of the receiver 1004, a Transmitter operated on a third frequency. The transmitters 1002 and 1003 can also pass through Replace receivers that operate at different frequencies. It's on this Way possible to send and receive at different frequencies without mutual Cause disturbances.

Since these networks prevent standing waves from forming on the transmission line, they can be used in a variety of ways to completely isolate a transmission line from their holding devices are used. Occasionally arise, especially when damp Weather, difficulties, as additional losses in the line due to the leakage current of the isolators be evoked. With the networks described you can overcome these difficulties! to encounter.

In Fig. 13, for. B. such a network is shown. 1301 is a radio frequency transmission line that connects devices 1302 and 1306 (e.g. transmitter, receiver, transmitting or receiving antenna) with one another. Such apparatus as 1302 are often mounted at a different height than the other part of the transmission line 1301, e.g. B. higher than this. This necessitates a bend 1303 in the transmission line, which is produced by means of an anchoring to the carrier 1304. With normal tensioning, the leakage currents of the insulators result in undesired impedances in the line, which change with the state of the atmosphere. These losses are avoided, for example, by a network according to FIG. 7, in which the length I of the part CD is chosen so that the ratio of the standing waves is equal to one. Since the network does not generate irregularities or reflections on the transmission line in this case, it acts as a perfect isolator which does not exert any undesirable influence on the transmission line. If the short-circuit wire is attached to the precisely _determined location, it is immaterial what is connected to the transmission line behind the short-circuit wire. Networks of this type are shown in FIG.

Such an insulation system can serve as a carrier and spreader at the same time if the individual components of the network are made from stiff conductors. Such an arrangement is shown in FIG. In the transmission line χχκ, I4OI a network 1405 is connected as a carrier, which can be dimensioned so that it acts like an insulator, and which is made of rods or tubes, so that there is a sufficient carrier effect. The network is preferably provided with 120 "short circuit wire 1406 (as in Fig. 2) to increase strength and immovably support the lower ends of the network without adversely affecting the properties of the network. as a sieve circle or as an impedance trans-

formator is used, can be made of rigid parts! so that it serves both as a holding device and as a spreader for the conductors of the transmission line.
5

Claims (14)

PATENT CLAIMS: 1. High frequency network for frequency-dependent coupling of two switching parts with the aid ίο a closed loop conductor with two Connection terminals on non-coincident Places, the loop of which is two adjacent, measured in length accordingly Current paths leads, characterized in that the properties of the network in desired Way influencing impedance element is present, which is connected to one of the side by side Conductor is connected to a suitable location between the terminals. 2. High frequency network according to claim 1, characterized in that in one of two Adjacent double lines existing network the impedance element to a is connected to the intermediate point of a pair of conductors. 3. High frequency network according to claim 2, characterized in that the sum of the Lengths of the double lines connected next to one another is equal to a wavelength. 4. High-frequency network according to claim 3, characterized in that the impedance element consists of a pair of conductors. 5. High-frequency network according to claim 4, characterized by a short-circuit clip, which the pair of conductors at a certain distance from the junction with a of the double lines connected next to one another are bridged. 6. High frequency network according to claim 2 to 5, characterized in that the network is switched into a transmission line in such a way that the one double line, the is not connected to the impedance element, lies in the course of the transmission line and which Another double line consists of two pairs of conductors, at the junction of which the impedance element connected. 7. High frequency network according to claim 2 to 6, characterized in that the length of the adjacent double lines is dimensioned so that it can be used as a blocking filter for one Frequency acts and that the impedance element in conjunction with the double lines has a blocking effect generated for a second frequency. 8. high-frequency network nadh claim 6, characterized in that the conductors of the Pairs of conductors at points equidistant from the conductors of the transmission line are connected. 9. High-frequency network nadh claim 8, characterized in that the with the transmission line connected pairs of conductors and that between the connection points with the Study of the transmission line lying in pairs of conductors are equal to each other. 10. High-frequency network according to one of the preceding claims, characterized in that that all conductors are rigid. 11. High frequency network nadh claim 1 to 10, characterized by the use for impedance matching with the network connected circuit arrangements. 12. High frequency network according to claim 11 for adapting a high-frequency apparatus to a transmission line, characterized in that, that the impedance element from the required dimensions of the side by side Double lines and the ratio of the maximum standing waves to theirs measured on the transmission line Minimum as well as the measured relative position of the maxima and minima determined and on is connected to a suitable point and the network with the impedance element at a Place the transmission line in this is switched on, which is determined by the value of the impedance element and the position of the standing waves on the transmission line is determined. 13. High frequency network according to claim 1 up to 10, characterized in that the network with the impedance element is dimensioned so that no impedance is introduced into the transmission line. 14. High frequency network according to one of the preceding claims, characterized by its use as a perfect insulator for tensioning the transmission line, in such a way that the tension insulators are connected to the short-circuit clip of the impedance element will. For this purpose 2 sheets of drawings © 509S36 8th SS