DE2300296A1 - REGULATING AMPLIFIER CIRCUIT - Google Patents

Description

PATENTANWÄLTE 8900 Augsburg-GSflgingeii, den

* on-Eich «tdorff-StraB · 10

dr. ing. E. LIEBAU

DIPL.ING. G.LIEBAU STSSÄk. L ⁹ SL, 2300296 Your sign

Thorn Electrical Industries Limited Thorn House, Upper Saint Martin's Lane, London WC2H 9ED / England

Active! Amplifier circuit

The invention relates to a circuit for simultaneously changing the gain of an amplifier and the DC level of its output such that the output level is substantially equal to an input level remains constant.

Such an amplifier is particularly advantageous for a color television receiver with a three-color electron beam tube, at which the three electron beams, the red, green and blue images on the screen of the Cathode ray tubes are produced by modulating the signals representing the picture content · Since the gray scale is a Scene displayed on the cathode ray tube screen, no different coloring between

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the darker areas, the middle tones and the light areas and there the differences between electron gun characteristics and changes in phosphorus efficiencies must have variable amplitudes Otherwise identical signals are fed to the three electron guns of the cathode ray tube in order to achieve the To display grayscale correctly.

The black elements of the original scene are represented by dots on the cathode ray tube screen reproduced, at which the three electron beam currents reach just zero at the same time. It is therefore desirable that a zero electron beam current for a particular level of input black and white signal control can be set to a video amplifier and that this setting remains unchanged when the The gain factor of the amplifier is subsequently adjusted to match the characteristics of the cathode ray tube will.

However, the change in the black and white signal control between the electron guns is usually thereby achieved that an identical black and white signal to all three video amplifiers of a color television receiver is supplied and then the voltage amplification factors of the amplifier in adaptation to the particular three-color cathode ray tube of the television receiver can be changed. A simple change in the gain factor of a video amplifier has the effect that the black level electron beam current is also changed in such a way that that such a system is difficult to adjust properly because the controls influence each other.

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The invention provides a control amplifier circuit in which the voltage gain of the Amplifier by the quotient of a first resistance value divided by a second resistance value is determined and at which the DC level of the amplifier output can be changed as a result, that a direct current voltage is varied in series with the second resistance value, the second resistance value and the DC voltage variable and the equivalent resistance or the are equivalent voltage of a circuit that has a first resistor connected between the amplifier and a point (which may be formed by either end) is connected across a second resistor, the is connected between a DC voltage source and a third resistor, which is connected to a reference voltage connected is; and wherein the third resistor is at least as great as the resistance of the second Resistance is so that when the gain of the amplifier is changed by the aforementioned Point or the value of the second resistor is changed, the DC voltage changes in a compensatory manner, so that the amplifier output level remains essentially constant for an amplifier input level.

The amplifier can be formed by a transistor in which the input is fed to the base, the output is taken at the collector, the first resistance value is formed by a resistor, which the Collector connects to a DC voltage source and the circuit is connected to the emitter.

The voltage of the direct current source to which the second resistor is connected can be measured by a Zener diode

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with a positive temperature coefficient of junction breakdown voltage be determined to provide a means of temperature stabilization by compensating for the negative temperature coefficient of the voltage of the Base against the emitter of the transistor.

One embodiment of the invention is exemplified below described in more detail in connection with the accompanying drawings, namely show:

Fig. 1 three amplifiers connected to a three-beam color television tube are connected;

2 shows a transistor amplifier with a conventional gain control;

3 shows a transistor amplifier with one according to the invention Gain control;

FIG. 4 shows an equivalent circuit for FIG. 3; FIG.

FIG. 5 shows the amplifier according to FIG. 3 with a Zen stabilized one DC voltage source;

6 shows the amplifier according to FIG. 3 with a modified gain control and

7 shows the amplifier according to FIG. 6 with a Zen stabilized one DC voltage source.

In Fig. 1 three video amplifiers 11, 12 and 13 are shown connected to a three-beam color television tube 10,

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2300298

They have a common black-and-white signal input path m and can either use the outputs at their outputs Cathodes or with the grids of the respective electron gun in the cathode ray tube 10 are connected. The amplifiers 11, 12 and 13 of such a color television receiver are voltage amplifiers of variable gain and usually have one Amplifier circuit of the type shown in FIG.

The amplifier of Fig. 2 has an npn silicon transistor 20 with a base 21, a collector 22 and an emitter 23. The collector 22 is connected to a positive Voltage source 25 connected via a collector load resistor 26 and directly with an output 27 connected. The emitter 23 is across an emitter load resistor 28 connected in series with a variable resistor 29 with a DC voltage source 30 which is negative with respect to the voltage source 25. The base 21 is through, an input signal voltage controlled on the signal path m.

If the collector resistor 26 has a resistance of Rc ohm and the total resistance of the resistors 28 and 29 is Re ohms, the gain of this amplifier is A = Rc / Re. At a certain base voltage Vb, the collector voltage Vc should block the flow of electrons in the electron gun to which the output 27 is connected and the emitter will have a voltage Ve which is approximately Vb - 0.7 volts. Under these conditions, if the voltage source 25 has a voltage of Vs volts and the voltage source 30 has a voltage of V ₁ volt, the emitter current is:

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¹ ^. = (Ve. - V _a ) / Re (1)

The base current is small compared to the emitter current, so that the collector current is approximately equal to the emitter current is. The collector voltage is therefore:

Vc: £ b Vs- (Ve - V ₁ ) Rc / Re

However, Rc / Re_ is the gain factor A of the amplifier, so that

Vc - Vs.- A (Ve - V ₁ ) ...... ·. (2)

The gain of the amplifier can be adjusted to match the electron gun to which this is connected by changing the resistor 29, which changes the value of Re, so that

A (max) = R £ / Re_ (min) (3)

A (min) = Rc / Re_ (max) (4)

From equation (2) arises in connection with equations (3) and ⁽¹ O, that a change of the amplification factor, the collector voltage Vc changes the amplifier according to this method for the particular base voltage Vb, so that a compensatory change in a

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the voltages Vs or V * becomes necessary.

This trait causes two difficulties, though Circuits of this form are used as video amplifiers in color television receivers. The first is in that the gray scale matching process is complicated by the change in black level when the separate preselected gain controls in adaptation to the characteristics of the cathode ray tube, with which the unit is operated can be set. The second difficulty arises when the full operational capabilities of transistors, components and supply voltages are used, in which case Signal output amplitude restrictions by operating a preset gain control of the form shown in Fig. 2 can be imposed

3 shows an amplifier according to the invention. This is the same as that described above in connection with FIG Amplifier similar, but the variable resistor 29 is replaced by a potentiometer 31, which is between the DC voltage source 30 and a grounded resistor is connected in series. The emitter resistor 38 is connected to the wiper 35 of the potentiometer 31.

If the resistance between the wiper 35 and the DC voltage source 30 via the potentiometer 31 _{is denoted by R 1} and the resistance between the wiper and the earth via the potentiometer 31 and the resistor 32 _{is denoted by R 2} , according to the Helmholtz theorem the Amplifier according to FIG. 3 can be represented by the circuit of FIG. 4, in which the emitter resistor 28 is connected via a resistor 33 to a direct voltage source 34, which resistor 33

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has the following value:

R ₃ = R ₁ R ₂ Z (R ₁ + R ₂ ) .... (5)

and the DC voltage source 31 has the following value:

+ R ₂ ) (6)

It follows, that is smaller than an area in which R _{1 and} R _2, if R ₁ increases from zero, Rg increases from zero, while V ₁ ¹ decreases from _V1. Therefore, as (Ve-V. ¹ ) decreases, A decreases with increasing R ₁ , so that a compensation measure is obtained in the value V at a certain Vb, where:

Vc ^ r Vs- A (Ve - V ₁ ¹ ) (2 ¹ )

Vc can be precisely determined for two positions of the wiper: when the wiper 35 is connected to the voltage source 30, the emitter current is _{assumed to be Ie 1} , while when the wiper 35 is connected to the other end of the potentiometer 31, the emitter current is assumed to be Ie _{2 is} assumed:

Ie ₁ = (Ve - V ₁ ) ZRe (7)

l £ ₂ = (Ve - V ₁ ^ Z (Re + R _c ) (8)

Using equations (5) and (6) one obtains from

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of equation (8)

± 2 * [ ^Ve - " ^v i ^R 2 ^{/ (R} l * ^R 2 ^ 1 ^; f ^R - ^{+ R} i ^R 2 ^{/ (R} l

Using equations (7) and (9), values for R ₁ and R ₂ can be found which give two values for the gain at which the collector voltages Vc for the particular base input Vb are equal. The value for R ₁ represents the resistance value of the potentiometer 31 and the value for R ₂ represents the resistance value of the resistor 32 to get the definite Vb.

In the case of a television receiver, the component values and supply voltages are selected as follows:

1) Re is chosen in conjunction with Rc to give the amplifier the required maximum gain obtain·

2) V. is chosen in conjunction with Re and Ve to get the required black level emitter current Ie ₁ in transistor 20 *

3) R ₃ is chosen to provide the minimum level gain required in conjunction with Re so that solutions for R ₁ and R ₂ can be found by equating equations (7) and (9).

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A further development of the circuit is shown in Fig. 5, in which the voltage source V. with a Zener diode 38 is provided in connection with a DC voltage source and a series resistor 37. In addition to Supply of a stabilized voltage V., the Zener diode 38 is also used as a source of stabilized voltage for other circuits in the receiver represented by a load 39.

In the case of the silicon transistor 20, the temperature coefficient of the base _{relative to the emitter p, d, V ßE is} approximately << 2 mV per ⁰ C increase in the junction temperature of the transistor. This change in the base against the emitter p, i.e. can lead to changes in the emitter current and thus in the collector current, which in the event of a temperature increase leads to a reduction in the transistor collector voltage.

However, if the Zener diode 38 has a positive temperature coefficient of the Zener voltage, a Kcw compensation measure can be taken for the change in the V _{ßE of} the transistor 20 in the event of a temperature change.

The »degree of compensation depends on the temperature rise of the transistor crystal and the Zener diode barrier layer, in the temperature coefficient of the Zener voltage and the position of the wiper 35 of the potentiometer 31 from «

The amplifier of FIG. 6 is that shown in FIG Identical with the exception that the potentiometer 31 is replaced by a variable resistor HO · The analysis

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the circuit remains unchanged for this form of gain control and the only difference is that in equations (5), (6) and (9) R _{2 is} now a constant instead of R ₁ ♦ R ₂ . This modification of the amplifier can of course be stabilized in the manner shown in Fig. 5, as shown in Fig. 7.

Of course, a compensating gain and bias control amplifier circuit according to the present invention can be made up of many types of amplifiers where the ratio of two resistance values is used to determine the gain «Im the invention can be particularly used with other types of transistors (including field effect transistors) or with tubes or with function amplifiers

In the embodiment described, the amplifiers are used in a color television circuit a common black-and-white signal path IA shown. However, amplifiers according to the invention can also be used for Television circuits used when using separate red, green and blue signal inputs to the display tube be and moreover in circuits in which überhapt no connection with the television consists.

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Claims (1)

Patent claims; I ₉ , control amplifier circuit in which the voltage gain of the amplifier is determined by the quotient of a first resistance value divided by a second resistance value and in which the direct current level of the amplifier output can be changed by changing a direct voltage in series with the second resistance value, characterized in that the second resistance and DC voltage are variable and the leakage resistance and voltage, respectively, of a network having a first resistor (28) interposed between the amplifier and a point (which may be formed by either end) at a second Resistor (31) is connected, which is connected between a DC voltage source (30) and a third resistor (32) which is connected to a reference voltage, the resistance of the third resistor (32) being at least as great as the resistance of the second resistor (31) is, s o that if the gain of the amplifier is changed by changing the mentioned point or the value of the second resistor (31), the mentioned DC voltage changes in a compensatory manner so that the amplifier output level remains essentially constant for an amplifier input level. 309838 / M. V 2300298 Circuit according to Claim 1, in which the amplifier is a transistor, characterized in that the input is fed to the base (21), the output (27) is taken from the collector (22), the first Resistance value is formed by a resistor (26) that connects the collector (22) to a DC voltage source (25), while the network with an emitter (23) is connected 3 «circuit according to claim 1 or 2, characterized in that that the voltage of the DC voltage source (30) to which the second resistor is connected through a zener diode (38) is determined Circuit according to Claims 2 and 3, characterized in that the Zener diode (38) has a positive temperature coefficient the junction breakdown voltage has to be a measure of the temperature stabilization through Compensation for the negative temperature coefficient of the voltage between the base and the emitter of the transistor (20). 5 «circuit according to the preceding claims, characterized in that that the second resistor (31) is formed by a potentiometer with a wiper, which connects the first resistor (28) to a variable point on the second resistor (31) « 6, video amplifier, characterized by a control amplifier according to the preceding claims. 309838/113 Blank page