DE874921C - Filter arranged between two amplifier tubes - Google Patents

Description

The invention relates to tube amplifier circuits in which a large gain and at the same time a gain that is as uniform as possible over a wide frequency range is required will. Such tube amplifiers are the subject of patent 756 014. According to the main patent is a Filter arranged between two amplifier tubes for the uniform transmission of a wide frequency band in the form of one of several equal half-links or half-links derived from these existing, built while avoiding the filter effect influencing ohmic resistances

and chain ladder consisting of reciprocally resistive longitudinal and transverse branches, in which the Tube capacities are used as a whole or as parts of the transverse capacitance of the filter, characterized in that that the initial series or initial cross reactance at the non-terminated end of the filter equal to the corresponding reactance of an entire filter element, and that the input current source of the filter is arranged parallel to a transverse capacitance located inside the filter. A The advantage of this arrangement is that the capacity of the non-closed end of the network

Work, d. H. usually the entrance end, one Has value twice that of an ordinary half-cross link, i.e. equal to that of a full cross member. The two transverse capacitances, which are represented by the tube capacitances - den, are therefore the same, and the amplifier's dependence on the frequency is particularly flat, almost up to the cutoff frequency of the low-pass network.

ίο In general, the output and input capacities of the tubes are not the same, so they must Precautions should be taken in the arrangement of the circles to reduce the total capacity on the grid and on to make the anode roughly equal to each other. This can e.g. B. happen that the stray capacitances, z. B. a coupling capacitor, in parallel with the anode or grid capacitance, which of the two just the smaller one is to be placed. In the event that there is a considerable difference between the capacities exists when they are z. B. behave like 2: 1, it is it is not desirable to double the smaller capacity because it is to be expected that an additional Capacity will reduce the effect that the actual capacity at the anode and grid could be achieved.

It is the main object of the present invention to provide an improved tube circuit according to the main patent indicate in which two tubes with unequal anode and grid capacities are coupled in this way are that a maximum value for the passband and the gain is reached without that additional capacitances need to be used in the circuit.

According to the invention, one is between two booster tubes arranged electrical filter according to the main patent designed such that with different large tube capacities forming the cross reactances that of the larger tube capacitance adjacent series inductances are coupled to one another in such a way that a low-pass filter network is formed will.

The load impedance is preferably designed so that it is the terminating impedance of the network forms. Their size is chosen so that in that Network no reflections occur. The end is preferably done with a longitudinal m-link.

In the following the invention is based on the figures to be described in more detail: In Fig. 1, a screen grid tube 5 is shown, the anode of a Inductance coil 6 and a capacitor 7 with the grid of a second screen grid tube 8 is connected, which grid is connected to a grid discharge resistor 9 is connected to the cathode. The cathode of the tube 5 is also via an inductance coil 11 connected to a load impedance, which is drawn to the left of the dotted line 10. The load impedance is with the positive terminal of the anode power source (not shown) tied together. The two coils 6 and 11 are coupled to one another and form with the dotted line indicated output capacitance of the tube 5 and the likewise indicated input capacitance of the tube 8 Elements of a low-pass network. 12 are the input terminals of tubes 5 and 13 are the output terminals of tube 8. The load impedance exists in the example shown from the resistor 17 and half a longitudinal w-element, which is formed by the inductance 14, the capacitor 15 and the inductance 16. Resistance 17 has an impedance that is equal to the nominal impedance of the network, making it an anechoic Completion of the network is guaranteed. The high voltage source is connected to terminals 18, which a capacitor 19 is connected in parallel.

Fig. 2 shows the same arrangement as Fig. 1; you can see here that the coupling between the coils 6 and 11 means nothing other than the attachment of a further inductance 20 between the connection point of the coils 6 and 11 and the anode of the tube 5. The size of the inductance 20 is between 6 and 11 due to the mutual inductance given.

The effect of the coupling is described in more detail with reference to Fig. 3. In this figure, the capacitor on the right-hand side of the network corresponds to the input capacitance of the tube 8, while the capacitor in the middle of the network corresponds to the output capacitance of the tube 5. The inductances, capacitors and resistors are indicated by symbols in this figure, which should be used in the following explanation. The tube 5 is a screen grid tube with high impedance, which has the property that it shows an output current of constant amplitude in the anode circuit with a fixed amplitude and variable frequency of the input voltage at the grid. The voltage which is fed to the grid of the following tube appears on the capacitor at S in Fig. 3, and the changes in this voltage indicate the high frequency sensitivity of the amplifier stage. According to the law of reciprocity, the constant current can be viewed as flowing into S. The voltage frequency sensitivity at P is then the frequency sensitivity of the amplifier.

If one considers S as the entry point, the network can be viewed as a composition of the following parts: a longitudinal m-terminating element, an m- element, where m for this element has the value%, a prototype half-element and another capacitance of the value aC . The inductance and capacitance of the prototype half-link have the values L and C, so that the capacitance at S is greater than the value of a normal half-link. In the event that a constant input impedance is to be achieved, the capacitance at S is twice as large as the value of a normal half-cross member, and accordingly the input impedance at 5 is then essentially constant, close to the cutoff frequency. The constant current that is fed to S generates a constant voltage at S, at all frequencies up to the cutoff frequency.

Now, with the usual capacitance value C at S instead of .2 C, the impedance Z _{s of} the filter, which occurs at S, is the impedance of the half cross member, and in accordance with the well known

In theory, it forms a resistance and is given by the following equation:

Where

χ =

I -

(O ₀

ίο is. (O ₀ is 2 π times the cutoff frequency and is given by the equation: O) ₀ LC = ι. ω is the angular frequency and R the nominal impedance of the filter [= ~ \. The ohmic resistance at Q is given by

A (I- (I- W ₁ ² ) X *)

Z ₀ =

X ^z

If the elements of the filter are essentially reactive, the performance at Q is the same as at S, and the voltage Vq at Q is therefore related to the voltage V _s at S as follows:

F _Q ²

Zg Zq v * Zq Vs Zg '

so

If one uses the capacitance of 2 C at S mm and a screen grid tube is used, V _{s is} constant regardless of the frequency. So if you put in the values for Zq and Z _s , is

From the theory of the w-filter, the following applies:

V _Q ι - (1 -

W ₁ ² )

(I)

(2)

(3)

For W ₁ <ι the sensitivity will increase with the frequency; for W ₁ > 1, which can be achieved by a mutual inductance between the coils, as in Fig. 1, the sensitivity falls with the frequency. The capacitance at P is determined by the tube capacitance and is equal to 2 W ₁ C, where C is the transverse capacitance of the elementary half-limb. C should be as small as possible so that the cut-off frequency for a given gain is as high as possible. For this reason it is necessary that W ₁ > ι.

We consider the case that W ₁ =] / if. As stated, a falling characteristic is caused, which can be corrected to a large extent by reducing the capacitance at 5 below the value of 2 C. The impedance at S and thus also the voltage will not increase with the frequency, and it can do so be established, that the frequency dependence at P is essentially flat up to a value of 0.7 of the cutoff frequency, while the passband is enlarged. The capacity is here z. B. (1 + a) C, i.e. H. the excess of the capacitance over the normal value of a half cross link is aC, where α is between zero and one. The impedance at 5 is now:

Vq I + X ² (I. • X -a ² ) ■ value Per- use V ₈ at S
is applicable: is ) · Χ so to this The voltage
portional. So I. (i - W ₁ ) ² X ² ] / (i T (I. - a) ² ■ x ² ■ ^ ι— (2— ; the above Equation (2) ² ) ■ x ⁱ under I. -W ₁ ² ) i \ V ₉
or (i -a ² ) ² Hi- (IW ₁ ■ x *. I.
Tr 2 a ² -W ₁ ² ; : 2 + (l- « ² ) (l-

A satisfactory characteristic is obtained when the right hand side of the last equation is made equal to one for χ - ¹ J ₂ ', then if

m _x ² - 2, a = 0.45:

+ 0.2 x ² - 0.8 x ^l

The amplitude does not vary by more than 5% up to χ = 0.7, ie up to a frequency which is equal to 0.7 of the cutoff frequency. By damping the coil 6 in Fig. 1, ie the coil between the anode and the grid, an even flatter characteristic is possible. The damping provided by the coil resistance that is already present is usually sufficient.

The ratio of the capacities (ft) is - ^ -.

In practice, this relationship is fixed, and it is necessary _{to choose W 1} and therefore α so that this relationship is met. In order to compare the effect of the amplifier stages described with the proposed amplifier stage, in which the ratio of the capacitances is equal to one, the theoretical transmission ranges should be compared for the same value of the anode capacitance of τομμΡ, since this is fixed in practice. For the simple network, the pass band and the gain is proportional to Rm ₀ , where m _{0 is} the cutoff frequency, expressed in angular frequencies.

According to the filter theory, Rm ₀ = -i, where C ₀ crosses

capacity of the elementary half-link ($ μμΡ) means.

For the amplifier circuit described and the same amplifier tube, the effect is again measured by the reciprocal value of the capacitance of the elementary half-limb. Since 2W ₁ C ₁ , which is equal to ΐομ / tF, means w _r times the full transverse capacitance

the elementary capacity is the same

The theoretical efficiency of the present amplifier is therefore improved _{by a factor of W 1.}

• In the discussion above it is assumed that the anode capacitance is greater than the grid capacitance. If the reverse is the case, then must. in the above consideration the position of the tubes can be swapped according to the reciprocity law. A practical embodiment for this case is shown in Fig. 4, in which the individual circuit elements are labeled with the corresponding symbols, as in Fig. Χ. In this embodiment, instead of the longitudinal terminating element shown in Fig. 1, a simple resistor 21 is used as the terminating element. In the circuit of Fig. 4, which is terminated by a pure resistor, the sensitivity curve shows a certain drop in the range of half the cutoff frequency. In the range of _^2/3 of the cut-off frequency, the curve rises. back to. These undesirable properties can be corrected by taking the mutual inductance M between the two. Coils 6 and 11-gives a value which is slightly larger than the value determined by the above calculation, ■

It was also found that in the arrangement according to FIG. 4 the values of the self-inductances of 6 and 11 differ only slightly from half and a quarter of the inductance L = A ² C ₁ , where R is the load resistance 21 and C _{1 is} the entire Transverse. capacity, ie the sum of the attode capacity of the tube 5 and the grid capacity of the tube 8 means. It was found to be the most favorable that the inductances 6 and 11 are given the values L / 2 and L / 4, respectively, and then the value of M is changed a little to compensate. When this has been carried out and when the highest working frequency fco is selected so that a deviation of no more than ± 0.2 decibels occurs in the sensitivity curve, and when the time constant is almost constant over the entire frequency range, then that at least 10 amplifier stages can be used for television purposes, all sizes for the circuit can be calculated to a good approximation from the relationship:

Af

= 0.17 {φ— ι) - o, o6 {p — i) ~,

where <p is the ratio between the anode capacitance of the tube 5 and the grid capacitance of the tube 8 and the value .des. Resistance 21 through the. Equation is given:. .

Claims (7)

Claims: -. - I. tube circuit in the form of a ^W-T ellenfüters as claimed in patent 756,014 that. in the case of tube capacitances of different sizes forming the transverse reactances, the longitudinal inductances adjacent to the larger tube capacitance are coupled to one another in such a way that a low-pass filter network is formed. 2. Filter according to claim 1, characterized in that the load impedance is formed is that it forms the terminating impedance of the network. 3. Filter. According to claim 2, characterized in that that the anode capacitance of the first ■ tube is greater than the grid capacitance of the second Tube and that the anode of the first tube is connected between the two inductors so that the grid capacitance of the second tube has a parallel reactance to that of the termination load far end of the network. 4. Filter according to claim 2, characterized in that the anpden capacitance of the one tube is smaller than the grid capacity of the second tube and that the anode of one tube with. to the Grid of the second tube - and the load impedance connected via one of the inductors is, while the -other "inductance between this one inductance and the load impedance is such that the anode capacitance one tube has a parallel reactance at the end of the network remote from the terminating load forms. 5. Filter according to claims 2 to 4, characterized in that that the load impedance is chosen so that no reflections occur in the network. . ... 6. Filter according to claim 4, characterized in that the following for the two inductances Calculations apply: the first inductance is L / 2, the second inductance is L / 4 L = 2? ² C ₁ , M = (0.17 (/> - i) ■ 0.06 {φ— ι) ² ; where R is the resistance of the terminating impedance, C ₁ . the sum of the anode and grid capacitances mentioned, M the mutual inductance of the two inductances, p the ratio of the. named grid,. and anode capacities, which is not greater than 2. 7. Filter, after. Claim 6, characterized in that that,; ; ...... is where fco means the maximum frequency to be transmitted through the network. 1 sheet of drawings © 5094 4.53