SU33580A1 - Method of frequency transformation down - Google Patents

Description

In earlier applications, the authors proposed a method of frequency transformation based on the use of oscillatory systems, processes in which are expressed by nonlinear differential levels, in other words, whose pargmeters are current or voltage functions.

If the number of conditions specified in the aforementioned proposals is observed, such a method can provide a reduction in frequency by two, three, etc., a number of times. The characteristic effect of frequency reduction for this method, as well as the special properties of such nonlinear systems, expressed, for example, in a special form of the resonance curve, etc., sharply separates this method from all other already known methods of frequency transformation and makes it especially valuable. in solving technical problems of yes.

6 of the description of the above mentioned snakes, special attention was paid to the transformation of the oscillatory processes in the systems, in which the parameters determining mainly the system frequency were used as parameters depending on the current or voltage. However, even in these applications, among the specific forms of implementation of the invention cited, devices have been described, with a series of

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The parameter determining the frequency of the system had a meiiem, and there was a change in the effective value of the system (the shunting of self-induction with a conductor or semiconductor, the resistance of which was a function of current or voltage of the system).

The subject of the present invention1: is the results of further theoretical and experimental studies of the indicated frequency transformation method, which showed the possibility of using {as a parameter, depending on the current or voltage, values that mainly determine not the natural frequency of the system, but its effective damping.

Especially advisable is the use of systems for the purposes of the present invention with systems containing a local energy source, included according to a scheme that permits the use of annual or partial compensation for losses in the system, since it is advisable. of such systems, the characteristics of which are related to the corresponding nonlinear systems, such as: regenerative, dinotron, etc. systems.

As the theory shows and experience confirms, in such systems, with a careful, well-defined selection of system parameters, it is possible to obtain the required subharmic KtiH transformable e. d.

Consideration of the case when, for example, an ordinary regenerative system acts on such a system

E.D.S., the essence of the invention is explained.

In this case, as is well known, it is assumed that if the regeneration system is not self-excited, then oscillations take place in the oscillatory circuit of the regenerative system, the main frequency of which is equal to the external EHS frequency, and with the appropriate tuning and selection of conditions allocate calabanes corresponding to one of the overtones of the external emf.

However, a theoretical or experimental study of these systems, as a particular case of nonlinear systems with variable parameters that determine, mainly the losses in the system, led to the possibility of obtaining new phenomena - a kind of excitation in such systems of oscillations of the subfrequency of external emf .

This new and technically important effect, which makes it possible to reduce the frequency in such a simple system, is the basis of the present invention.

A method is proposed to transform the frequency down in systems containing a local energy source that is connected in accordance with a scheme that can be used to partially or fully compensate for losses in the system.

The essence of the invention is that as such systems, oscillatory systems tuned to a subharmonic frequency transformer are used, in which systems the parameters determining mainly the losses in these systems are a function of current or voltage.

In FIG. 1 shows a diagram of the device by means of which the proposed method is carried out; FIG. 2 and 3 diagrams of devices that correspond to the modification of the basic method. Dialogically in FIG. 4 shows a diagram of an apparatus for carrying out another modification of the methods of FIG. 1, 2, 3.

One of the simplest forms of implementation of the proposed method, shown in FIG. 1 is any of the regenerative systems known per se, the oscillating circuit A is tuned to the secondary subfrequency, and the parameters of the coaxial system (feedback, lamp permeability, constant voltages on the anole and grids, etc.) are matched in a certain way.

Signs that determine the suitability of a particular system for applying it to frequency transformation in accordance with the present invention are: i) the presence of a certain periodic dependence of the system loss on current or voltage and 2) the presence tuned to the secondary frequency (sub-frequency) oscillatory system.

The presence of such properties in the system makes it possible, according to the present / invention, with the appropriate selection of its parameters, to apply its dll of the selection of a subharmonic transformable ed, s. It should be noted that the proposed method should be applied for the purposes of radio reception in the device according to the author. swith th 30727 as described in this application, i.e., in the form of a cascade transform, frequency mapping, as shown by further studies; however, the total number of stages of such a device can be significantly reduced by applying multiple frequency transformations in the same stage. Figs 2 and 3 illustrate exemplary forms of the implementation of this method for Regene; ative system. As can be seen from the drawing, in this case, the device consists of oscillatory systems connected in the circuit of one of the electrodes, for example, in the junction anode circuit, each connected via a feedback circuit to the circuit of the second electrode (in the case of a grid from the grid). The tuning of both systems must correspond to the magnitude of the transformed frequency. For example, at the frequency of the emf to be transformed, contour setting. / may have

the value of y, t, e, in the eGo system will be

frequency transformation will occur twice, and in the circuit // the frequency will be further transformed, for example, another two times, and therefore the tuning of the circuit // will correspond to (II

to frequency.

An order of a pony; to neither the frequency of a single system szhemnzig from the system and the conditions of the system, ne still can say that P1 was out of order for the wrong user, i.e. chech

60L; and / 1O VALICH / IMZUG KD {UVieHrbl

at higher levels in the frequency spectrum, I express uviM zizigimosti current in the system og prigigisgo ngchenzhenn, the easier it is; dialect, palu1; (mv bolse nshkoD with / harmonic system.

Peegemu, in neporyy with sp / chach predstazl ingerzs of pechulenlg systems of high nonlinearity, pozel yu; u dzhstvit aa ome ym zngn; Bethge zachachitelnaz on r-tvKSH "Gchesgoty. For the present invention, the method of calculating the non-linearity of the systems is obtained, based on the dependence of the i / (v) dependence: the characteristic of the non-hLHloge section of the system, V is not straightforward; r-i, is not directly defined by the oscillatory process, and all of them ogred themselves were not dependent. (-,) and therefore (} The foregoing is explained in Fig. 4 of the attached drawing, gde pr; dsgztten, one of the possible fair wasps-C2Stvle; c. so "system.

As can be seen from the drawing, this scheme is different from the riD pfg scheme. 1 by the fact that the voltage on the grid of the lamp / is not directly induced by the current in circuit L through the dependence ii7. And j, where

(i) is the coefficient of mutual induction-1i, and / is the current in the circuit, and depends on the current of the lamp 2, which in the SEE1O queue is determined by the voltage on the grid, because of) the current in the lamp.

Than nepingy: –––––––––––––––––––––––––––:

5 on the grid of the lamp 2 tlchch4g sdglatl glycine dependently on L / -, -, i.e., if

ABOUT .

Include cjii one lamp, the current kotor will determine the female / 1e voltage on the lamp grid 2.

The subject matter of the invention.

Claims (4)

1. The method of transferring frequencies downwards in systems that are socialist {Н1щщщ мзззННННННННННННННННННН эн эн эн эн эн эн р р р р р р в в в в в в в в 1гггггггггггггггг п п п п п п п п п п п п п п п п п;;; ;,,,енен его част част част част част част част част част част част partial or full compensation for losses in the system, characterized in that 1% of the systems have 1 or 4 compensation of losses in the system, characterized by that 1 or 4 systems of examples have 1 or 4 full compensation of losses in the system, differing Transforming the frequencies of the oscillating systems on a subgrinker, and the xzoy systems, the parameters determined by the loss of these systems are a function of the current or voltage. 2. Accepting the method of shermash frequency trap down by p. 1, characterized in that, for the purpose of multiple frequencies: in a single ssh-.ie, several stresses are used, which are built-in oscillatory systems, with a common (ep2 "tronnay lamp), the first is not depending on the loss of the B system on the applied electromotive force. 3. Pei way to transform chzstogi vchiz on PP. 1 and 2, in order to increase the order of frequency transformation down, a combination of one of the three three-way or multielectrode lamps, resulting in the highest level, is necessary for a system. 4.When the method of frequency conversion down, especially for circuits of radio reception pa. , application of cascade frequency transformation. TO h, 3 1-l / I I, 1 5) T t FIG. copyright svpstslstiu L. II. Maidelltam. and -N. D. Papa.1, 33580