DE1780664U - TUNED - HIGH FREQUENCY VIBRANT CIRCUIT. - Google Patents

Description

Orientation Reg. 5716 / Ple / Dü / Roman Klinger-1 LEBSE-H22SaS21Si The tuning of a high frequency resonant circuit can be carried out by means of a variable condensate, an adjustable coil or by changing these two frequency-determining elements at the same time.

A variable capacitor is usually used for capacitive tuning. The inductive tuning can be done by spherical variometers, immersion variometers with an iron core or by means of a grinding wire variometer.

All of these tuning elements are relatively large and suitable not for device constructions in miniature construction. - It is also not possible a given frequency change as a function of using commercially available tuning elements to achieve from the angle of rotation. Should z. B. the resonance resistance of a resonant circuit remain constant during the vote, it must be capacitive and at the same time take place inductively. For a multi-circuit tunable filter arrangement When using components in the usual form, the dimensions are very unfavorable.

For devices that use printed circuit technology it is now desirable to include such tunable circuits and filters as well in this construction to execute. There are high frequency switches in Known printed version, in which the feeds to the holder segments are designed as Leo derivatives, which are opened by soldering a short circuit a certain frequency can be tuned. It is also possible to have a similar one Solder the coil to these leads. It is also known to use a short-circuit device to slide over two ring-shaped conductors, one of which is interrupted several times is. These interruption points are bridged with inductances. The order Acts as a range switch and for fine tuning at high frequencies at the same time In contrast, high-frequency oscillating circuits according to the invention allow a predetermined one continuous or discontinuous frequency response of the vote. You are in technology of the printed circuits can be manufactured or can be part of a printed circuit Be circuit.

High-frequency oscillating circuits according to the invention have the characteristic that a given frequency response of the vote by the shape of the conductive Deposits is achieved, with either only the inductance or also the inductance and the capacity of the resonant circuit can be changed. Based on FIGS. 1 to 7 the invention is to be explained in more detail.

Figure 1 shows a carrier plate 1 made of insulating material on both sides an electrically conductive layer (e.g.

Copper foil) 2, 4 applied in the technique of printed circuits is. On one side the conductive layer is down to the ring 2 and the spokes 3 removed.

The surface on the reverse side remains unchanged. One end of the circular ring 2 can be connected to the floor covering on the reverse side, so that the grinder 3 has one Short-circuits part of the circular ring. Figure 6 shows the equivalent circuit diagram of the tunable High frequency resonant circuit. As you can easily see, the voting changes Inductance and capacitance, so that you can with appropriate training of the coating 2 a constant L / C ratio, respectively. achieve a constant resonance resistance can. The spokes 5 can be used for adjustment to a predetermined frequency curve can be used depending on the angle of rotation. (Z.

B. by scraping off the film on printed circuits).

Fig. 2 shows an embodiment in which the carrier plate 1 is only on one side is covered with a film 2. The movable grinder 3 connects the two circular rings, so that mainly a change in inductance is achieved.

Another type of shaping according to FIG. 4, in which depending from the angle of rotation, the area and the diameter of the effective conductive coating changed enables a further increase in the frequency variation. In this version the angle of rotation can also be made greater than 36C °. The short circuit which the two rubbers connects is movable in the radial direction and is pressed against the inner surface of the opening, for example by a compression spring.

Fig. 5 shows an embodiment in which the two coverings of the carrier plate 1 are formed into spirals 2, 3, which are spaced apart from the thickness of the carrier plate face. The structure thus represents a line, the length of which is by means of of the Kurzsohlußbügel 4 can be changed continuously.

Fig. 7 shows the course of the resonance frequency of an arrangement according to Figure 1 as a function of the angle of rotation when the spokes 5 are designed so that within the ranges from spoke to spoke the relative change in capacitance is greater than the relative change in inductance.

Such a shape allows the entire frequency variation Divide into areas of different steepness (band spread).

Attachments: drawings (7 figures) 4 claims

Claims (3)

Claims 1.) Manufactured in technology for printed circuits, tunable high-frequency resonant circuit with adjustable short-circuit clip, d a d u It is indicated that a given frequency response of the vote is achieved by the shaping of the conductive coverings, either only the Inductance cuer also the inductance and the capacitance of the resonant circuit can be changed is. 2.) Tunable high-frequency resonant circuit according to claim 1, dadu rchgekisiert that the conductive coatings are formed on one or both sides circular or as a spiral, so that the angle of rotation of the vote can be up to 3690 or a multiple of 36 ° can. 3.) Tunable high-frequency oscillating circuit according to claim 1 and 2, d adurchgekisiert that there are additional, predominantly acting as capacitance surfaces on the suffering coverings that cause a desired discontinuous frequency change or serve as balancing points that z. B. can be changed by scraping nen. 4.) Tunable high-frequency resonant circuit according to claim 1 to 3e characterized in that a recess in which the conductive linings-bearing plate fulfills the function of a cam for guiding the short-circuit clip.