DE756014C - Filter arranged between two amplifier tubes - Google Patents

Description

When transmitting broad frequency bands with essentially more uniform Reinforcement, as z. B. in amplifiers for television purposes - the case jst is the upper one Cutoff frequency due to the unavoidable shunt capacitances, i.e. the,; grid-cathode capacitances, Grid-anode capacities, anode-cathode capacities and lead capacities are specified. It is the Object of the invention, despite these inevitable shunt capacities: a Decrease in the degree of reinforcement in the area of prevent high frequencies. -.;

In Fig. Ι an amplifier is in the

known. . Resistance capacitance coupling shown. When the anode resistance R is small compared to the internal resistance of the tube V ₁ , it can be shown that the equation holds. -

P'T - - 7 ^ ~ >.

where µ is the gain of the tube V ₁ . containing amplifier stage, / is the frequency of the band to be transmitted and S is the slope. Here, C is the total capacitance which is parallel to the anode resistance R ; k is a constant

The coupling circuit between the tubes V ₁ and F ₂ acts as a low-pass filter. The cutoff frequency / is known by the equation

= ι

given. For a common resistor-coupled amplifier, this is

k -

2Jl!

The size of the constant k now determines

is the size of the product μ · f. If f is large, as it is e.g. B. in the case of amplifiers for television purposes, as mentioned, a large gain μ can only be achieved if k assumes a large value, since the effective parallel capacitance C does not fall below a minimum value, the size of which depends on the tube used depends, can be reduced.

It is known that the value of k in a circuit of FIG. 1 can be increased in that an inductance suitable size either in series with the resistor, or in the train of the line from the anode of the tube V ₁ to the control grid of the tube V _{2 is} switched on.

It is also known to couple two tubes to one another through a filter network, wherein the shunt capacitances of the tubes are used to build the filter. A filter is usually composed of several half-links. Depending on, how these half-links are connected to one another creates a filter of the π-type or of the Γ-type. Next, the usual filters are constructed in such a way that they are mutually exclusive resistance reciprocal longitudinal and transverse branches are composed. If this the inductances are in the longitudinal train and the capacitors in the transverse train, a low-pass filter is created; if reversed the capacitors A high-pass filter is created. When the capacitors are connected as cross capacitors and with the inductances are tuned to a certain frequency and the parts formed in this way in certain Coupled in a way, one obtains a band filter.

As already stated above, these filters are composed of reciprocal resistance longitudinal and Ouerzweig composed. The initial reactances are identical to the corresponding longitudinal or transverse reactances. With filters of this known type, the impedance is not over the entire bandwidth constant. Therefore, the known filters are not suitable, one tube with another To couple tube o. The like. If a substantially over a large frequency range uniform reinforcement should be present.

The invention relates to a filter arranged between two amplifier tubes for uniform transmission of a wide frequency band in the form of one of several equal half-links or existing half-links derived from these, under Avoidance of built-up ohmic resistances which influence the filter effect and chain conductor consisting of reciprocal longitudinal and transverse branches with reciprocal resistance, in which the tube capacities are used as a whole or as parts of the transverse capacitance of the filter. According to the invention is such Arrangement of the initial series or initial cross reactance at the non-terminated end of the filter is dimensioned to be equal to the corresponding reactance of an entire filter element and the input power source of the filter in parallel with one located inside the filter Transverse capacitance arranged.

While with the usual filters the initial series or initial transverse reactance at the non-terminated end of the filter is equal to half the corresponding reactance of a whole filter part, twice this value is used in the arrangement according to the invention in order to pass through the use of such a filter in broadband amplifiers significantly increases of the gain factor without compromising the bandwidth.

It is known that the initial series or Initial cross reactance equal to the corresponding one To make reactance of an entire filter part, however, this well-known served ioo Arrangement not for coupling two tubes of a broadband amplifier.

In the arrangement according to the invention, one of series reactances and Shunt capacitors existing low-pass filter of the capacitor at the non-terminated End chosen to be the same size as that of a whole cross member.

The use of the tube capacitance as a whole or as a partial transverse capacitance of the filter results in a considerably larger value of k, so that in the arrangement according to the invention without changing the bandwidth, the gain is considerably increased compared to previously known circuits.

The termination of the filter used in the arrangement according to the invention can be made from a simple resistor of suitable value, as below to be explained in more detail, contain a derived w-half-term.

In a preferred embodiment of the invention, the filter is designed as a low-pass filter and contains one and a half parts of a network of the π-type. Each half-link of the network consists of a series inductance L ₀ and a transverse capacitance C ₀ . One end of the filter is terminated by the half-limb and a resistor. ίο The other end is bridged by a capacitance of size 2 C _0.

Such a filter has an input impedance that is essentially up to the cutoff frequency is constant. This results from the following equations.

The input impedance Z _{0 of} a conventional filter is given by the equation when terminated with the characteristic impedance

R _n

Z _n =

Where R _{n is} the nominal value of the wave

It is given by the

^a 5 resistance.
relationship

ω ₀ is the cutoff frequency for which the relationship applies

^ω ° ^ ITeT '

If the transverse capacitance is doubled at the non-terminated end, then applies to the input impedance Z of the modified network has the following relationship:

Z =

ι + j ω C _n Z _n

R _n

ω_γ \ (τ + ω * C ₀ * R ₀ *)

CO ₀ )

ω *

ιΛ-

ω ₀

But now C ₀ ■ R ₀ = ---.

Hence | Zj = R ₀ , ie the amount of the input impedance is equal to the nominal value

of the wave resistance.
If now the entrance of this network

the constant output current fed to a screen grid tube is the voltage constant at the cross capacitors for all frequencies up to the cutoff frequency, provided that the filter is exactly terminated with the wave impedance. The deviation from this condition is close to the Cutoff frequency depends on the extent to which the terminating resistance matches the characteristic impedance of the network is adapted.

It can be shown that all filters have the constant AVType, that is, at all filters made up of reciprocal resistance in series and shunt branches that result in the same constant input impedance, if the design of the initial series or initial transverse reactance is in the specified Way is done. So if the invention in a filter that consists of a or several T-links is applied, the input impedance can be made constant if the The value of a row element at the input corresponds to a whole row element and not half a row element like the Filter theory corresponds and usually is the case.

If the filter consists of a single half-part, the cross or series reactance at the end remote from the termination within the meaning of the invention are made of the same value as. the theo retic value of a whole cross or series reactance. There can also be an or several half-links of the filter can be replaced by derived half-links.

The invention will be described in more detail with reference to FIGS. 2 and 3. In the circuit of FIG. 2, the amplifier contains two screen grid tubes V ₁ and V ₂ . The anode of the first tube is connected to the control grid of the second by a series circuit consisting of a blocking capacitor C ₁ and an inductance L _1. A grid leakage resistor Rq of the usual size is provided for the second tube. This resistance is so great that the filter effect is not influenced by it, just as the blocking capacitor C ₁ is dimensioned so that it does not play a role in the filter effect. The anode-cathode capacitance of the tube V ₁ together with the no associated stray capacitances of the lines and other switching elements forms a low-pass filter of the π-type, which is made up of 1V2 half-elements, with the inductance L ₁ , part of the inductance L ₂ , the Control grid cathode capacitance of the tube V ₂ and the associated stray capacitances. The two capacities of the network are shown by dashed lines.

The filter is terminated by the m-half element that is considered for this purpose. This Degree consists of a part of the

Inductance L ₂ , which is connected in series with the anode resistance R of the tube V ₁ between the anode of the tube V ₁ and the positive pole of the anode voltage source, not shown, as well as from the series connection of a capacitor C ₂ and an inductance L ₃ , which is connected between the Junction of R and L ₂ and the cathode is connected. The remainder of the inductance L ₂ forms the series reactance of the first half-limb of the filter.

When the inductance L _{1 has} the value 2 L ₀

and the effective external capacity of the network

■ works the value '2 C ₀ , then the values of the three elements of the derived »i half-member are given by the relationships:

C ₂ = nt C _n

τ

-m *

A suitable value for in in the described arrangement is 0.7. In this case the network represents an essentially constant input impedance for the tube V ₁ up to the cut-off frequency. If the two Ouerkapazi activities of the filter are made equal, then the constant k has the value

The values of the two transverse capacitances can be made equal by choosing the position of the different lines of the inductance L ₁ . However, they are preferably balanced in that the capacitor C ₁ and the bleeder resistor R ₀ are switched on either to the left or right of the inductance L ₁ , so that their capacitance to ground becomes the smaller of the two capacitances, the anode-cathode capacitance of the tube V ₁ or grid-cathode capacitance of the tube V ₂ , added.

Instead of the tube V ₂ , the shunt capacitances of which form the output transverse capacitance of the network, a cathode ray tube can also be used, the capacitance of which between the modulator electrode and the cathode represents the desired external capacitance of the network in this case.

By using a derived "im" as a termination, the Uniformity of the amplitude characteristic of the network can be further improved. In In this case, a largely flat characteristic curve is obtained parallel to the abscissa up to 90% of the cutoff frequency.

If the tube V _{1 is} a triode, the internal resistance of this triode, which is parallel to the anode-cathode path, must also be taken into account. The values of the elements C ₂ , L ₂ and L ₃ can then be | can be made smaller. The value of L ₁ and the value of the resistor connected in parallel to it are only slightly influenced by this.

In Fig. 3 another arrangement according to the invention is shown in which a band filter is used to couple two tubes. The elements which correspond to the elements in FIG. 2 are provided with the same reference symbols. The band filter consists of the anode-cathode capacitance of the tube V ₁ and the inductance L ₅ on the one hand and the grid-cathode capacitance of the tube V ₂ and an inductance L ₈ on the other hand, which are _{coupled together by an inductance L 1} and a coupling capacitor C. . The inductances L ₃ , L ₆ and L ₁ are matched with their associated capacitances to the mean frequency of the frequency band. The filter is closed by a derived »z-half-term. This termination, which differs from that of the circuit of FIG. 2 , is enclosed by the dashed line T of FIG. 3 together with a series element of the filter. The inductance L ₁ represents a coil which, together with the bypass capacitor C, does not play a role in the operation of the filter. In this embodiment of the invention, the reactance of the inductance L _{0 is made} equal to the reactance of the inductance L ₅ and the grid-cathode capacitance of the tube V _{2 is made} equal to the anode-cathode capacitance of the tube V ₁ .

Claims (4)

Patent claims: i. A filter arranged between two amplifier tubes for the uniform transmission of a wide frequency band in the form of a chain conductor consisting of several equal half-links or half-links derived from these, built up from ohmic resistances which influence the filter effect and made up of reciprocal resistance in longitudinal and transverse branches, in which the tube capacitances as whole or as parts of the transverse capacitances of the filter are used, characterized in that the initial series or initial transverse reactance at the non-terminated end of the filter is equal to the corresponding reactance of an entire filter element and that the input current n ₅ source of the filter is parallel to an im Inside the filter lying Ouerkapazit is arranged. 2. Network according to claim 1, characterized in that the terminating impedance contains a derived »z-half-member. 3. Network according to claim 1, characterized characterized in that the terminating impedance contains a derived 'm' half-term. 4. Network according to claim 1, characterized in that the in the anode feed line of the upstream tube into the reflection-free, preferably designed as an m-half-member Terminating impedance of the filter chain. To differentiate the subject matter of the invention from the state of the art, the granting procedure the following publications have been considered: German patent specification No. 507 825, 477,985,452,495;
British Patent Nos. 410147,436,734; USA patents No. 1 925 340, ι 918 393, ι 587 574 · 1 sheet of drawings 2616 12.5i