DE1232284B - Frequency-selective arrangement for the transmission of very short electromagnetic waves - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

H03h

HOIp

German KL: 21g-34

Number: 1232 284

File number: M13124 IX d / 21 g

Filing date: February 26, 1952

Opened on: January 12, 1967

The invention is concerned with a frequency selective arrangement for use at very high levels Frequencies, especially for filters of the line type, in which instead of point-like distributed Impedances lengths of a high frequency line are used. Such a filter has a passband and a definite pole.

In the previously used frequency-selective arrangements of the above type, it is common practice to achieve the required characteristics of frequency selectivity with the aid of one or more stub lines connected in series or in parallel. F i g. 1 shows a typical example of this type for the case that a frequency Z _{1 is to be} blocked and an adjacent frequency / _{2 is to be} allowed through.

According to FIG. 1 is connected to a main transmission line, which consists of an inner pipe conductor Ml arranged concentrically in an outer pipe conductor MO , a branched branch line in parallel, which consists of an inner conductor Tl which runs concentrically in an outer conductor TO. The stub has a greater length I ₁ and a shorter length I ₂ , each of which can be short-circuited or open at the distal end. If the greater length is open at the end, its length is an odd multiple of a quarter wavelength at the cutoff frequency; when shorted, its length is an integral multiple of half a wavelength at that frequency. The short length I ₂ has a reactance at the pass frequency which is as largely the same as and opposite to that of the long length.

This arrangement has the considerable practical drawback that, due to the limit value of the possible characteristic impedance of the transmission line from which the stub line consists, the impedance formed by the stub line for the pass frequency / _{2 is} necessarily far below the theoretically required value and accordingly a considerable loss occurs even if the greater length I _{1 is made} very long. This typical error is also present in other known arrangements with branched stub lines.

An arrangement is also known in which networks connected to transmission lines are made from Line pieces for broadband adaptation, in particular of antennas, are used on transmitters. This filter arrangement however, has quite considerable losses, since the connecting lines are A / 4 long.

The aim of the invention is to reduce these errors and to provide improved and effective filters or similar frequency-selective arrangements for transmission
very short electromagnetic waves

Applicant:

The Marconi Company, Limited, London

Representative:

Dr.-Ing. B. Johannesson, patent attorney,

Hanover, Göttinger Chaussee 76

Named as inventor:

Boleslaw Marian Sosin, Chelmsford, Essex

(Great Britain)

Claimed priority:
Great Britain from February 26, 1951,

dated November 28, 1951 (4688)

to create borrowed arrangements of the type mentioned which the losses are reduced to an acceptable level without being excessively long and unwieldy Having to use stub lines.

In a frequency-selective circuit arrangement for the transmission of very short electromagnetic waves, in which the main line between the input and the output of the arrangement has at least one T-shaped stub line whose impedance acting on the main line shows an extremely low and a very high impedance at the prescribed frequency spacing, It is therefore proposed according to the invention that the length / _{3 of} the section of the T-shaped stub line, which connects the other two sections of this stub line with the main line, deviates from a quarter or an integral multiple of a quarter of the wavelength values to which frequencies correspond within the range , which includes both the frequency Z ₁ , at which the stub reaches the lowest impedance value at its connection point with the main line, and the frequency / 2, at which a very high impedance at the stub connection ert occurs, while the following relationships apply to the lengths I ₁ and I _{2 of} the other two sections of the T-shaped stub line, depending on their termination:

609 757/321

Section with length I ₁

Section with length I ₂

open at the end:

h + I ₃ ^ - 4

short-circuited at the end:

_ «A ₂

I ₁

short-circuited at the end:

short-circuited at the end:

open at the end:

,,, (β + I) A ₂

I ₁ + / ₂ «ti

4th
open at the end:

I ₁ + 4 - " ^A

thereby means

A _{1 is} the wavelength that can be determined from the frequency Z _{1 , A 2 is} the wavelength corresponding to the frequency / ₂ , η is an odd number.

Due to the design according to the invention, the disruptive in frequency-selective arrangements Internal losses are reduced to such a level as is not the case with the previously known filter arrangements was possible.

At the pass frequency, the input resistance of the filter arrangement connected to the transmission line exhibits parallel resonance behavior. Since the losses grow with the square of the current, the conduction losses in a reflective closed line are mainly concentrated on points of maximum current. By dimensioning according to the teachings of the invention it is achieved that the length I _{3 of} the connecting line is not equal to a quarter wavelength at the desired blocking frequency; more precisely, the length will differ somewhat from the exact odd multiple of the quarter wavelength due to the presence of the length / _2. Then the length I _{2 is} short-circuited, and I ₁ + I ₂ are given a length of approximately an odd multiple of a quarter wavelength at the pass frequency, this length being slightly different from the exact odd multiple of the quarter wavelength due to the presence of the length I _3. When I _{1 is} shorted, I ₁ + I ₃ gets a length that is about an even multiple of a quarter wavelength at the cutoff frequency, and when I _{2 is} also shorted, I ₁ + I ₂ gets a length that is about an even multiple of Quarter wavelength at the pass frequency. If section I ₂ on

Is open at the end, it has a length which is around -j-

- based on the pass frequency - differs from the case in which I _{2 is} short-circuited at the end.

In these arrangements, all other things being equal, the ratio of I ₂ : 1 _{1 is} much greater than in the known arrangement according to FIG. 1, and practically with the same length of the stub line, the losses in an arrangement according to the invention are compared with a known arrangement according to FIG. 1 decreased to about a quarter or less. In addition, high currents are kept away from the junction with the main transmission line, and a greater correspondence between practical and theoretical implementation can be achieved than with known arrangements.

F i g. FIG. 3 shows an arrangement according to the invention with a T-stub line which goes into the main transmission line is connected in series rather than in parallel as in FIG. 2. In Fig. 3 the same reference numerals are used as in Fig. 2, so that Fig. 3 can be easily understood.

The "reciprocal" T-stub line can be used as an alternative to the "straight" T-stub line of the invention can be used. F i g. 4 and 5 show reciprocal T-arrays connected in parallel to the Main line are connected. According to the illustration in FIG. 4 and 5, these arrangements don't have that Appearance of T-members, but they actually are, as can be seen from FIG. 2 a and 4 a results. F i g. 2 a is the corresponding block diagram of the stub line of FIG. 2 and 3, while F i g. 4 a the corresponding Block diagram of the branch line according to FIG. 4 and 5 is. In the F i g. 2, 2 a, 3, 4, 4a and 5 are the same reference numerals used to make comparison easier. In the case of the reciprocal T-branch line, the lengths the different parts have the same values as the corresponding lengths of the straight T-stub line; however, the distal end of the corresponding portion of the reciprocal T-stub is short closed when that of the straight T-stub line is open, and vice versa. A reciprocal T-stub line can also be placed in series with the main line, but can in this case the arrangement of an insulating stub line may be necessary.

The known branch lines, as shown in FIG. 1, for example, or the reciprocal Arrangement (in which two stub lines are in series) have the deficiencies already mentioned. The invention avoids by adding the intermediate length 4 to the transmission line is to transform the known arrangement in a T-stub line, these shortcomings, with the frequency dependence is changed and the losses can be made very small.

In all cases, I ₃ can be of any length that

deviates from -r or a multiple thereof. In 4

In all of the above cases, by choosing _{a suitable value for / 3} , the frequency / _l5 at which the impedance is approximately zero can be arbitrarily selected either below or above the frequency / ₂ at which the impedance is approximately infinite.

For any two specific frequencies f _x and / ₂ in one of the cases in the table above, the lengths I ₁ , I ₂ and 4 can be freely selected, in such a way that the bandwidth at Z _{1 can} gradually be changed from wide to narrow and the bandwidth at / ₂ can be changed gradually from narrow to wide. In other words, values can be chosen for the lengths I ₁ , I ₂ and 4 which result in a wide band for J _{1 and a narrow band for / 2} , or vice versa, or any intermediate state of the bandwidth, with a widening of the band at Z _{1 is accompanied} by a narrowing of the band at / ₂ , and vice versa.

Claims (4)

Patent claims: 1. Frequency-selective circuit arrangement for the transmission of very short electromagnetic waves, in which the main line between the input and the output of the arrangement has at least one T-shaped stub line whose impedance acting on the main line shows an extremely low and a very high impedance at a prescribed frequency spacing, characterized in that the length (Z ₃ ) of the section of the T-shaped stub line, which connects the other two sections of this stub line to the main line, deviates from a quarter or an integral multiple of a quarter of the wavelength values to which frequencies correspond within the range, which includes both the frequency (Z ₁ ) at which the stub line reaches the lowest impedance value at its connection point with the main line, and the frequency (Z ₂ ) at which a very high impedance value occurs at the stub line connection, during end for the lengths (I ₁ and / ₂ ) of the other two sections of the T-shaped stub line, depending on their termination, the following relationships apply: Section with length I ₁ Section with length / ₂ open at the end short-circuited at the end: short-circuited at the end: at the end 4 + shorted: _ (B + I) A ₂ open at the end: (n + I) A ₂ k + h «* open at the end:
ηλ ₂ h + k «* thereby means X _{1 is} the wavelength that can be determined from the frequency f _x, A _{2 is} the wavelength corresponding to the frequency / _2, η is an odd number. 2. Arrangement according to claim 1, characterized in that the branch line of the main line is connected in parallel. 3. Modification of the arrangement according to claim 1, characterized by such a design of the Branch line that this is in series with the main line. 4. modification of the arrangement according to claim 2 or 3, characterized in that the stub line is realized in reciprocal form. Considered publications:
British Patent No. 457 911;
U.S. Patent Nos. 2,321,521, 2,128,400. 1 sheet of drawings 609 757/321 1.67 © Bundesdruckerei Berlin