DE834703C - Vibration generator - Google Patents

Description

Vibration generator The connection refers to the generation of vibrations with the help of semiconductor amplifiers and new ones that are useful for this purpose Self-excitation circles.

The main object of the invention is to provide a semiconductor oscillator to withdraw a maximum benefit amount and to charge it, under while maintaining self-excitation at a desired power level.

The invention uses a three-electrode semiconductor amplifier as a central element. This central element contains a small block of semiconductor material, such as z. B. Germanium, which in its basic form has at least three electrodes, which are electrically coupled to it and which act as control, pick-up and base electrodes are designated. The control electrode and the collection electrode can be tip contact electrodes which form rectifier contacts with the block, while the base electrode may consist of a metallic film covering that has a low resistance contact forms. The control electrode can be biased for conduction in the forward direction while biasing the pickup electrode for conduction in the opposite direction is set. Applying a signal to the control electrode creates one Signal frequency current in the pick-up electrode and in an external one connected to it Circle that can contain a load. Due to certain processes that play in the block, increases in tension occur in the load, des Current and power of the original signal. The device, which various forms can be given is and should be called a transistor are also referred to in this description in the present description.

By feeding back part of the output voltage in an appropriate way Phase and its application to the input terminals, the device can be caused to to vibrate at a frequency determined by the outer circular elements; Such a self-excitation circle comes about, for example, when the decrease circle is fed back to the control circuit. If you take the example of the usual vacuum tube circuit takes as a model, the load with the output electrode, namely the pick-up electrode, arranged in a circle.

The special features of the transistor, however, differ greatly from those the usual vacuum tubes. In the case of these deviations, the focus is on the fact that the impedance of the control circuit is much less than the impedance of the pick-up circuit. In particular, the control impedance is typically on the order of 500 ohms, while the pick-up impedance is of the order of 20,000 to 50,000 Ohm lies. Therefore, the control electrode conducts a substantial signal frequency current off, compared with the grid of a vacuum tube, which is essentially at all does not discharge any current.

The present invention proceeds from these and other characteristics Differences between the transistor and the usual vacuum tube out and brings Construction designs in proposal, which take full advantage of these differences draw. In detail, it is recognized that in the transistor oscillator, the decrease circuit the power source forms, while the control circuit, the tuning elements and the Load are all power consumers and therefore none of these three circles can be reliably adapted for yourself that rather the decrease circle as a power source in terms of impedance to the load, the tuning elements and the steering committee as a whole should be adapted and that as well the optimal arrangement is not simply one, whereby the load, the voting elements and the control circuit in their entirety from your acceptance circuit receive a maximum benefit amount, but that there is a further requirement, to achieve optimal operation: namely that the performance between the load and the tuning elements on the one hand and the control circuit on the other is in such a way that the control circuit receives only so much from the acceptance performance, that the self-excitation is maintained during the loading and the tuning elements receive the rest of the performance.

The invention provides special circular arrangements in which these general principles are embodied and applied; and formulas are developed which enable the designer to find the optimal Determine the values of the circle parameters.

It is a feature of the invention that a load of less Impedance is preferably connected to the control circuit of the transistor <@ i-s and not with the decrease circle, which would be the case if you followed the analogy with the `- <ikuumrölirenoszillatortechnik would follow. The load in the generally connected either in parallel with or in series with the control electrode; that depends on the particular circumstances.

The invention will be fully understood from the following in detail detailed description of certain exemplary embodiments, namely in connection with the drawing; In the drawing, Fig. r shows a schematic Circuit diagram of a transistor oscillator network, which according to the invention is fed back and loaded; 2 shows an equivalent circuit diagram, which is used for the explanation the mode of operation of the lireis according to FIG. i is expedient; Figures 3, 4 and 5 are schematic Diagrams of transistor oscillator networks, which alternatives of the oscillator network according to Fig. i.

In Fig. I of the drawing, a transistor is shown, the a block or a slice i of semiconductor material, such as. B. germanium, which has been prepared in a suitable manner, contains and has a control electrode 2, a pick-up electrode 3 and a base electrode 4. A direct current source, e.g. B. a battery 5, and a tuned parallel resonant circuit is arranged, which consists of a coil 6 in parallel with a capacitor 7. A direct current source 8 and a load resistor RLt are arranged in series between the base electrode and the control electrode. A blocking capacitor g is located between a tap io on the coil 6 and the control electrode 2 of the transistor. The polarities and voltages of the direct current sources 5 and 8 are selected so that the control electrode in the @ '<ii-w: irtsrichtung, d.li. in, the low impedance direction, the pickup electrode will work in the opposite direction, that is, in the high impedance direction. In particular, for a transistor made of N '= Iyp-germanium, the control electrode can have an average potential of the order of magnitude of + 0.5 volts and the pick-up electrode a potential of -4o volts, both of which are measured with reference to the base electrode.

Under these bias conditions, the control circuit of a typical transistor has a low ac impedance, on the order of 300 ohms, while the pick-up circuit has a relatively high ac impedance of about 30,000 ohms. If a signal is impressed on the control electrode in addition to the bias, an amplified copy of the same is also applied to a suitable terminating impedance in the pick-up circuit. The power gains obtained in this way can be 100: 1 or 20 decibels. Accordingly, in an ideal oscillator, only about one-half of the power supplied by the pick-up circuit needed to be fed back to excite the control circuit; The oscillator according to the present invention approaches this ideal, but in practice does not achieve it insofar as additional power has to be supplied to the control circuit, which causes a moderate overload and a corresponding reduction in power in the transistor for the purpose of maintaining continuous oscillation despite possible The operation of the oscillator can be fully understood from Figure 2, wherein the transistor is shown in the form known as a quadrupole equivalent circuit 12, with input terminals 2 'and 4' and output terminals 3 'and 4' , the feeders 2 ', 3' and 4 'correspond to transistor electrodes 2, 3 and 4, respectively. The general principles on which the use of such a four-pole equivalent circuit is based to represent a network with an amplifier or other active elements are explained in an article by LC Peterson, entitled "Equivalent Circuits of Linear Active Four Terminal Networks" in Volume 27 of the Bell System Technical Journal, Oct. 1948, page 593. The variable or alternating current characteristics of the transistor are fully illustrated by the elements shown in the drawing, namely an inherent impedance Z and a transmission impedance Z12, in the inner path leading from the control electrode to the base electrode, and an inherent impedance Z22 and a transmission impedance Z21 in the inner path leading from the pickup electrode to the base. For any frequency in the range from zero to about i megahertz, these impedances are essentially phase-free. Accordingly, in the following they are assumed to be pure resistances. For the sake of simplicity, the two transmission impedances can be viewed as generators, as illustrated in FIG. 2, each of which generates a potential which is proportional to the current iii. The opposite branch of the equivalent circuit. This means that the passage of a current i, in the inward direction to the pick-up electrode results in a potential V 'equal to Z "i, in the path leading from the control electrode to the base electrode, the polarity being such that the control connection becomes more positive Thus, the passage of a current i, in the inward direction to the pickup electrode creates a potential V "equal to" 1.21i in the path leading from the pickup electrode to the base electrode with a polarity such that the pickup electrode becomes more positive. The magnitudes of these four impedances can in a typical case have the following values: Z, 1 = 400 µm Z1., = 100 ohms Z22 = 30,000 ohms Z21 = 50,000 ohms. It is now assumed that the control current i has a suitable operating value which, as mentioned, causes a moderate overload or exceeds the linear range of the transistor; for this value the values Z11, Z12, "1.2z and Z21 should be determined according to the principles of the invention. The consumption current is then where Z2 represents the total external impedance towards the decrease circle, as symbolized by the arrow line in FIG. The total power supplied to impedance Z2 will be a maximum, according to well known principles, when Z2 = Z22. This is a desirable condition that should be used as a prerequisite for dimensioning the parameters of the oscillator. Accordingly is The alternating component v "of the decrease potential is and the total service coming from the acceptance group is In order to generate the assumed current i, a voltage v must be applied to the control electrode. Their size is determined by ans Accordingly, a benefit amount must correspond accordingly are supplied to the control electrode; this service amount can be taken from the service P available at the acceptance group. In order to symbolize the method according to the invention for carrying out this extraction, an ideal transformer 13 is shown, which couples the acceptance circuit to the control circuit. It has a ratio of primary turns N to secondary turns N2, which is preferably the same: Now the total power P supplied by the acceptance circuit, in the absence of other power sources, must be equal to the sum of the powers P. , P r and Py, which are absorbed by the control circuit, by the tuning elements L, r, C or by the load. Accordingly, P = P .. + PT -i-- Pr..

But if vibrations are to be maintained in the assumed power level, P, a fixed size, so that the available for distribution to the tuning elements and the load power PI '+ Pz = P, -P. The distribution of this power between the tuning elements and the load is left to the designer and must generally be viewed as a compromise between conflicting considerations of maximum output power on the one hand and frequency stability and purity of the waveform on the other. If optimal purity of the waveform is required, then the tuning elements must also take over the greater part of the available power, and Pp is greater than PL. On the other hand, if waveform purity and stability are not the dominant considerations while demanding the greatest possible output, then PL is greater than PT. A reasonable compromise, which does justice to the conditions that frequently occur in practice, consists in distributing the available power evenly between the tuning elements and the load; after that is where RT and RL are the effective resistances of the Al tuning elements and the external load, respectively. It follows from this that and With the help of the above equations, all parameters ve, z, e, P, and P, as quantities of i, and the four internal impedances of the transistor, which, taking into account the overload, apply to the selected value of i, can be determined . If the values of these impedances given above are taken for a sinusoidal control current of i milliamps (quadratic: mean value), the following typical values result: 1e = i milliamperes 1e = 0.833 mini amps v, = 25 volts P, = 20.8 mini watts v, = 0317 volts P, = 0.117 mini watt NI N2 = 79 PT = 10.24 mini watts PL = 10.24 milliwatts RT = 61,000 ohms RL = 9.75 ohms. When comparing the values of P, Pe, PT and PL given in this table, it can be seen that the sum of the two last-mentioned values is equal to the difference between the two first-mentioned values; This means that after the control circuit has been supplied with the power required to maintain the desired condition of self-excitation, the entire remaining power is used up economically in the tuning elements and the external load; In addition, it should be noted that the two last-named power consumers consume the same amount of power, in accordance with the assumed compromise.

If, in the example explained, a larger value for the variable Control current i would have been taken, e.g. B. 2 milliamps, it would be different effective values for Zri, Z12, 722 and Z21 from the non-linearity of the transistor so that neither i nor s "would increase in direct proportion however, there would be some increase in these quantities. In particular, it can be seen that when the peak amplitude of the alternating component (2 ") of the decrease potential is increased so as to equal the value of the permanent bias component thereof reached, the pickup electrode no longer works in the opposite direction, but rapidly assumes a low impedance associated with forward operation. This rapid change in the pick-up impedance has a corresponding distortion of the Oscillator output, which may be undesirable, but on the other On the other hand, it creates a limiting effect that tends to reduce the amplitude of v, to be regulated at a value which is almost equal to the take-off preload. at In some applications, the latter feature can be used to advantage, since in the circle according to FIG. 2 they also determine the amplitude of the voltage z "at the load RL stabilized.

It should be returned to FIG. I, from which it can be seen is that the same can be derived from Fig. 2 by only the ideal Transformer 13 is replaced by a tap 1o at the tuning inductance 6, at a point where the N2 - @@ 'indentations from the lower end of the winding, the has a total of NI turns, is removed, and that one has a blocking capacitor 9 and DC power sources 5 and 8 added. The load I? L, of low impedance corresponds to the load RL according to FIG. 2. On the other hand, if desired, a Load RL: of high impedance connected to part or all of the inductance 6 be e.g. B. by means of a tap 14, which is placed so that it is the load delivers the service assigned to it. When that's done, #o becomes a moderately large one Resistance or inductance is used in place of the load RL, this element being it draws little or no power from the oscillator but a path for Forms direct current to the control electrode.

3 shows another embodiment in which the impedance conversion, which is symbolized by the ideal transformer 13 in FIG Control electrode 2 is connected to their common terminal. The mode of operation here is essentially the same as in FIG. 2, the function of the ideal transformer 13 being taken over by the two capacitors according to known principles. In order to ensure the same deformation ratio, it is necessary that or In Fig. 4 another embodiment of the invention is shown, wherein a secondary winding 2o, which is closely coupled to a primary winding 21 tuned by means of a capacitor 22, is used in order to supply power at low impedance to the control electrode 2 and the load RL. In this case the turns ratio is the primary to the secondary side as is the case with the ideal transformer 13 of FIG. An advantage of this arrangement over those according to FIGS. I and 3 is that a direct current path to the control electrode is created, through the secondary winding 20, and that therefore the load RL does not have to carry the steady component of the control current.

On the other hand, this arrangement forms a path from the source 5 to the control electrode 2, which only includes the impedance of the secondary winding 20. This impedance exists at very low frequencies and in the limit for direct current only from the residual resistance of the coil 20. At the same low frequencies the capacitor 24 forms a very small shunt with the resistor 23, see above that the current feedback from the acceptance circuit directly to the control circuit, independently is promoted by the transformer 20, 21. This situation can lead to instability or wild vibrations at unwanted frequencies. These can go through Switching on a resistor 25 in series with the control electrode can be avoided. Another resistor 26 is in series with the pick-up electrode for a possible Damage to the transistor as a result of the passage of increased consumption current of the source 5 to prevent. To avoid having this resistance at the desired If the oscillation frequency absorbs significant power, it is done by means of a capacitor 7 bridged.

Fig. 4 also illustrates the use of a self-excitation arrangement, a resistor 23 bridged by a capacitor 24 between the Base terminal 4 of the transistor and the connection point of the control and acceptance paths connected.

A typical transistor is under normal biasing conditions the direct current component of the drainage current flowing from the transistor to the outside, the inward flowing direct current of the control electrode predominate; this leads to, that there is an inward current to the base terminal. If this base current is passed through a suitable resistor, it can be used to biasing the base electrode negative and thus the control electrode with reference to make the base positive. In accordance with this, the DC power source can be omitted in the control path. The bias resistor 23 is by means of the capacitor 24 bridged to prevent him from taking the AC components of the base current impaired at the vibration frequency.

Figure 5 shows yet another circuit configuration, embodying the principles of the invention and employing a voltage resonance circuit L ', r', C. The primary winding 3o of a transformer 31 with a turns ratio is between the DC power source and the pickup electrode 3 connected. The secondary winding 32 is in series with a tuning inductance L ', which has a resistor y', a tuning capacitor C , the load RL and the path leading from the base electrode to the control electrode within the transistor. The control bias can be provided by means of a source 8 and a resistor 33, which preferably has a value of at least a multiple of the control base impedance. The same alternating current i flows in this circuit. by each of the elements listed above in series. (The weak current flowing through resistor 33 shunted to the control electrode is neglected). Accordingly, the amounts of power allocated to the load, voltage resonance elements and control circuit are proportional to their associated ohmic impedances and these can be appropriately sized according to the general principles described in connection with FIG. The transformer turns ratio is then selected so that the decrease impedance Z22 is matched to the impedance Z2 opposite it, namely the impedance represented by the primary winding of the transformer. Thus, the entire available power of the transistor is used profitably by distributing it to the tuning elements, the control circuit and the load as required.

Claims (7)

PATENT CLAIMS: i. Vibration generator with a semiconductor amplifier, which has a control electrode, a pick-up electrode and a base electrode, characterized in that the output power of the tapping circuit is greater than the operationally required output power of the control circuit, with a feedback path leads from the acceptance circuit to the control circuit of the amplifier to the self-excitation in of the amplifier and loop comprising the feedback path maintain, and a load is coupled to the control circuit. 2. Vibration generator according to claim i, characterized in that with the control circuit of the amplifier coupled load is of low impedance. 3. Vibration generator according to claim i or 2, characterized in that the load is connected to part of the loop and that adjustable impedance matching means is provided in the feedback path are to match the impedance of the pick-up circuit to the combined impedance of the control circuit and adapt to the load. Vibration generator according to claim i or 2, characterized characterized in that the load and also frequency tuning elements to the loop are connected, and that adjustable impedance matching means in the feedback path lie in order to match the decrease impedance to the combined impedances of the control circuit, to adapt the tuning elements and the load. Vibration generator according to claim i or 2, characterized in that a parallel oscillation circuit consisting of a Coil and a capacitor shunted to it, between the Pickup and the base electrode is connected, and that the feedback path of a tap between the coil ends. 6. Vibration generator according to claim i or 2, characterized in that a parallel oscillation circuit consisting of a Coil and two capacitors connected in series and shunted to it exists, is connected between the pickup and the base electrode, and that the Feedback path from a conductive connection from the common terminal of the two capacitors to the control circuit. 7. Vibration generator according to claim i or 2, characterized in that a transformer with its primary winding between the pickup and base electrodes and with a secondary winding between the base electrode and the control electrode are connected to the feedback path to form, and that a chip. magnetic resonance circuit comprising a coil and a capacitor includes, is in series with the secondary winding. B. vibration generator according to claim 7, characterized in that the load is in series with the secondary winding. G. Vibration generator according to claim 1 or 2, characterized in that the feedback path is formed by a parallel oscillation circuit, which has a primary coil and a to this in the shunted capacitor, in series connection between acceptance and base electrode, as well as a secondary coil that is inductive to the primary coil is coupled and connected in series between the control and base electrodes, the load being arranged parallel to the secondary coil. lo. Vibration generator according to claim g, characterized in that a protective resistor in series between the secondary winding and the control electrode is connected. ii. Vibration generator according to claim 10, characterized in that a bridging capacitor is shunted is arranged to the protective resistor.