NL8201613A - CONTROL CIRCUIT FOR AUDIO OR VIDEO EQUIPMENT. - Google Patents

Description

. * v 4 κ PHN 10.327 1 N.V. Philips' Incandescent lamp factories in Eindhoven "Control circuit for audio or video equipment" A. Background of the invention ΑΠ). Field of the invention

The invention relates to a control circuit 5 for use in, for example, audio or video equipment and comprising at least one control circuit for controlling, for example, color saturation / brightness or contrast in a color TV receiver, or pitch or volume in a TV receiver or in audio equipment .

10 A (2). Description of the prior art

Control circuits for setting an adjustable quantity of an information signal; for example, the color saturation, brightness or contrast of a color TV signal, have been used for many years. Large parts of such control circuits are currently designed as an integrated circuit with a certain number of connection pins. A typical example of an integrated circuit for use in a control circuit for a TV receiver is, for example, the applicant's IC TDA 3560. This integrated circuit, fitted with 28 20 connection pins, contains three control circuits; namely, a color saturation control circuit, a contrast control circuit and a brightness control circuit. An analog information signal is applied to each of these control circuits through an information signal input, and each control circuit provides an analog output signal.

Each control circuit is also provided with a control input which is coupled via a control signal connecting pin to the output of a control signal source which supplies a control signal. In the current control circuits this control signal is available in analog form and the control signal source is usually designed as a potentiometer.

Partly due to the introduction of the microprocessor, the aim is to digitize as much as possible, as yet available in analog form, signals such as the above-mentioned control signals, 8201613 f * '\ Λ * EHN 10.327 2, or better yet directly in digital form. to generate. If the control signals are digital, the control circuit as a whole and more particularly also the part thereof, which is designed as an integrated circuit, must have a different structure than when the control signals are available in analog form.

In practice this would mean that two distinct integrated circuits (ICs) would have to be manufactured for the same purpose, namely one suitable for receiving analog control signals and one suitable for receiving digital control signals. However, this is very uneconomical.

B. Summary of the invention

The object of the invention is to indicate a control circuit which is largely in the form of an integrated circuit ai, wherein this integrated circuit can be supplied with either analog control signals or digital control signals, and in which the number of pins of the integrated circuit, relative to the original number of connection pins, does not need to be increased.

According to the invention there is therefore provided for this purpose: - a detection circuit which is connected to the control signal connecting pin and which provides an indication signal which is representative of the nature (analog or digital) of the control signal, * - a first switching device which is controlled by the indication signal and which is equipped with:. an input connected to the control signal terminal pin; . a first output connected to the control input of the control circuit; . a second output 30 - coupling means for coupling the second output of the first switching means to the control input of the control circuit.

C. Brief description of the figures

Fig. 1 schematically shows the structure of a known control circuit for use in a color TV receiver;

Fig. 2 shows a first exemplary embodiment of the control circuit according to the invention;

Fig. 3 shows a control signal source for generating a 8201613 EHN 10.327 3 <i i Λ t a digital control signal for use in the FIG. 2 shown control circuit;

Fig. 4 shows a detection circuit for use in the control circuit shown in FIG. 2 is shown; FIG. 5 shows an interface circuit for use in the control circuit shown in FIG. 2 is shown;

Fig. 6 shows a second exemplary embodiment of the control circuit according to the invention;

Fig. 7 shows an address decoder for use in the control circuit shown in FIG. 6 is shown.

D. Description of some output examples D (1). A known control circuit 15. 1 schematically shows a known control circuit in which the measures according to the invention can be advantageously applied and which is partly formed by an integrated circuit 1. As an example it will be assumed that this integrated circuit is formed by the IC TDA 356Q of applicant such as described in the Philips Data Handbook No. IC2 05-80 of May 1980 and whose construction for clarity's sake is only partially shown in Figs. 1 is shown. -

This control circuit is provided with a connecting pin 2 to which a luminance signal Y can be applied, which is applied via an amplifier 3 to the information signal input 4 (1,1) of a contrast control circuit 4 (1). This also has a: control input 4 (1,2) and a signal output 4 (1,3). The control input 4 (1,2) is connected to a connecting pin 5 (1) to which an analog contrast signal 30 generated by a contrast control signal source 6 (1) A is applied.

The control circuit is also provided with a connecting pin 7 to which a color information signal CHR can be applied and which is then applied via an amplifier 5-1 to the information signal input 4 (2,1) of a color saturation control circuit (4). 2) This also has a first control input 4 (2,2), a second control input 4 (2,3) and a signal output 4 (2,4). The first control input 4 (2,2) is connected with a terminal pin 5 (2) to which an analogous color saturation generated by a color saturation control signal source 6 (2) A 8201613 it *% \

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.3 10,327 4 control signal (= Saturation) is applied. The second control input 4 (2,3) is connected to the connecting pin 5 (1) and thus also receives the contrast control signal C1.

In addition to the aforementioned connection pins, there is also a g connection pin 5 (3) to which an analog brightness control signal BRA (= Brightness) generated by a brightness control signal source 6 (3) A is applied and which is applied to a control input 4 (3.2) of brightness control circuit 4 (3).

The one shown in FIG. 1, control circuit 10 is furthermore provided with a demodulator circuit 8 whose input 8 (0) is connected via a connecting pin 9, a delay line 10 and a connecting pin 11 to the signal output 4 (2,4) of the control circuit 4 (2 ). This demodulator circuit 8 is provided with the three outputs 8 (1), 8 (2) and 8 (3) at which the respective difference signals B-Y, 15 G-Y and R-Y occur. Each difference signal is applied to an adder 12 (.) Of an adder circuit 12 to which the luminance signal Y which occurs at the signal output 4 (1,3) of the contrast control circuit 4 (1) is also supplied. Adder circuit 12 therefore supplies the blue color signal B, the green color signal G and 20 the red color signal R. These color signals are each applied to a terminal circuit 13 (.) Of the brightness control circuit 4 (3), in which the signal level which occurs during the line blanking time (the blanking level) is clamped to a fixed value. This fixed value is determined by the level of the brightness control signal BRA applied to the terminal pin 5 (3). The signals supplied by these clamping circuits 13 (.) Can be supplied via connection pins 14, 15, 16 to the picture tube of the TV receiver.

As shown in Fig. 1, in this control circuit, a capacitor 17 is connected to the connecting pin 5 (1) parallel to the contrast control signal source 6 (1) A. The voltage on the terminal pin 5 (1) is equal to the voltage across this capacitor 17, which in turn is determined by the setting of the source 6 (1) A. In practice, it is possible that the contrast control signal source 6 (1) A is set such that the instantaneous value of one of the three signals B, G or R is so high that overloading of the picture tube can thereby occur. To counteract this, each clamping circuit 13 (.) Is provided with an additional output which is connected to 8201613

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PHN 10.327 '5 «*» locks the input of a peak value detector 18. This provides an output current as soon as the additional output of at least one of the clamping circuits has a voltage higher than a certain threshold value. In practice, this threshold value is 9 volts. The current supplied by this detector is supplied via the connecting pin 5 (1) to the capacitor 17 which is discharged thereby. As a result, the voltage at the connecting pin 5 (1) decreases, and so does the instantaneous value of each of the signals B, G and R.

10 D (2). Improvements of the well-known control switching controller <.

To now of the in FIG. 1, the known control circuit is shown to enable the integrated part 1 to optionally receive either analog control signals or digital control signals, this known control circuit can be modified in the manner shown in FIG. 2. Each connecting pin 5 (.) Is not directly connected to the control input 4 (., 2) of the associated control circuit 4 (.), But via a commutation circuit 19 (.). It is provided with a detection circuit 2Q (.), The input of which is connected to the associated terminal pin and 20 which provides an indication signal representative of the nature of the control signal applied to the relevant terminal pin. It will be assumed that this indication signal is a bivalent signal that has a value VQ if the control signal is an analog signal and that has a value if the control signal is a digital signal. This indication signal controls a switching device 21 (.), Which is only shown symbolically. It is provided with an information signal input 22 (.) Which is also connected to the connecting pin 5 {.)? and furthermore of two outputs 23 (.) and 24 (.) which are connected directly and via an interface circuit 25 (.) to the control input 4 (., 2) of the associated control circuit 4 (.).

As schematically indicated in the figure, the connecting pin 5 (-) can be connected either to a control signal source 6 (.) A which supplies an analog control signal SA, BR or, or a control signal source 6 (.) D which provides a digital control signal SQ, BRp or CD. -If now, more specifically, when the control signal source 6 (.) A is connected to the connecting pin 5 (.), The indication signal assumes the value VQ, whereby the analog control signal via output 23 (.) Of the 8201613 PHN 10,327 6 ft ♦ switching device 21 (.) is directly supplied to the control input 4 (., 2) of the control circuit 4 (.). If, on the other hand, the control signal source 6 (.) D is connected to the connecting pin 5 (-), the indication signal assumes the value and the digital control signal 5 is applied to the switching device 21 (.) Via the output 24 (.). interface circuit 25 (.). Therein, this digital control signal is converted into an analog control signal which can be processed by the associated control circuit 4 (.).

It should be noted that the interface circuit 25 (1) cannot process the current which may be supplied by the peak value detector 18 if a digital control signal is applied to the terminal pin 5 (1). In that case this peak value detector 18 will have to be deactivated. In Figure 2 this is symbolized by the switch 26 connected to the output of the peak value detector 18 and which is also controlled by the indication signal supplied by the detection circuit 20 (1). In this case, switch 26 becomes conductive when the indication signal has the value VQ and thus the control signal source 6 (1) A is connected to the connecting pin 5 (1). Also now parallel to this control signal source 6 (1) A, the capacitor 17 is discharged and discharged by the current supplied by the peak value detector 18. If the indication signal has the value V ^, this means that the control signal source 6 (1) D is connected to the connecting pin 5 (1) and switch 26 becomes non-conducting.

25 D (3). Embodiments of some components

As well as in the control circuit shown in Fig. 1, will also be used for the in FIG. 2, the control signal source 6 (.) A providing an analog control signal (S ^, BRA, or C ^) is assumed to be a potentiometer circuit. For proper operation of the devices shown in FIG. 2, this potentiometer circuit is dimensioned such that its output voltage is in a first voltage interval ranging, for example, from about 8 volts to about 11 volts. (In the known control circuit this voltage interval runs from.

35 approx. 1 volt to approx. 4 volts).

The control signal source 6 (.) D which supplies a digital control signal can be output on the circuit shown in FIG. 3 shown in the manner shown. It is equipped with a clock pulse generator 27 which just supplies a frequency of 8201613 4 PHN 10.327 7 * * *> 5 to 10 Hz clock pulses. These clock pulses are now applied via a switch 28 to the output of the control signal source. Switch 28 is controlled by an operating button 29 and is conductive when this operating button 29 is operated. Switch 28 then adjusts a number of 5 clock pulses proportional to the time it is conductive.

If the operating key 29 is not operated, switch 28 is non-conducting and no clock pulses appear at the output of this control signal source. The clock pulse generator 27 is dimensioned such that the clock pulses have a 0 and a 1 level corresponding to 10 voltage values located in a second voltage interval. For example, the 0 level corresponds to a voltage of 0 volts and a 1 level corresponds to a voltage of 5 volts.

By ensuring that the output voltage of the (analog) control signal source 6 (.) A is in a different voltage interval than the output voltage of the (digital) control signal source 6 (.) D, the detection circuit 20 (.) Can the indication signal supplies are designed as a level detector. An exemplary embodiment of this is shown in FIG. 4. It is provided with two transformers 30 and 31, the emitters of which are connected together to earth potential via a current source circuit 20 32. The collector of each of these two transistors is connected via a collector resistor 33, 34 to a battery 35 which supplies a voltage of, for example, +12 volts. A voltage divider consisting of resistors 36 and 37 is arranged parallel to this battery 35. These resistors are chosen such that the voltage divider point has a voltage of 7 volts.

This voltage divider point is now connected at the base of transistor 30.

The input 38 of this detection circuit is connected to the base of transistor 31 and the output 39 is connected to the collector of transistor 30. More specifically, resistors 33 and 30 and the current I supplied by current source circuit 32 are supplied. Dimensioned such that each of transistors 30 and 31 acts as a switch. This detection circuit 20 (.) Now supplies an output voltage of VQ = 7 volts at its output 39 if the input voltage is greater than 7 volts. On the other hand, it supplies an output voltage of = 12 volts if its input voltage is less than 7 volts.

The clock pulses transmitted by the switch 28 (Fig. 3) are applied via switching device 21 (.) (Fig. 2) to the interface circuit 25 (.). An exemplary embodiment of this is shown in FIG. 5. It is provided with a counting circuit 40 to which said clock pulses are applied. The counting position of this counting circuit is supplied via parallel outputs (one bit per output) to a digital-analog converter 41 which supplies at its output a voltage which is proportional to this counting position. The counting circuit 40 has a memory function so that a certain counting position is not lost and the digital-analog converter 41 continuously supplies the same output voltage as long as the push button 29 10 is not operated.

D (4). Control circuit with central control signal source

The control circuit shown in FIG. 2 is provided with three separate control signal sources 6 (.) D, each of which can be connected via its own line qp to the associated terminals. Figure 6 shows an embodiment of a control circuit in which all control signals are generated by a central control signal source 42. This can for instance be formed in the manner described in British patent application No. 2,053,539 A 20 by a microprocessor with a keyboard connected thereto. . In the illustrated embodiment shown, two lines are connected to this central control signal source, namely a data line 43 and a clock line 44. The central control signal source supplies all control signals and supplies them bit-serially and successively to the data line 43. It supplies clock pulses 44 to the clock line 44 at the same rate as the bits of the control signals occur on the data line. This clock line makes the central control signal source suitable for connection to a so-called serial system bus.

Each control signal supplied by the central control signal source consists of an address code followed by a number of information bits which in turn are followed by a stop sign. The address code indicates for which of the control circuits the subsequent information bits are intended. The stop sign indicates that no further bits are present for the selected control circuit at this time.

As shown in Figure 6, the data line 43 is connectable to the connector pin 5 (2) and the clock line is connectable 8201613 «EHN 10.327 9 * to the connector pin 5 (3). Both these connecting pins are now also connected to the input 22 (.) Of the switching device 21 (.), Which is now also controlled by the indication signal supplied by the indication circuit 2Q (.). The output 23 (.) Of this switching device is again directly connected to the control input 4 (., 2) of the associated control circuit 4 (.). More specifically, these are the color saturation control circuit 4 (2) and the brightness control circuit 4 (3). Output 24 (2) of switching device 21 (2) is connected to the input 45 (1) of a switching device 45, which is indicated here only symbolically. It is equipped with a rest output 45 (2) and three signal outputs 46 (.).

Each signal output 46 (.) Is connected via the associated interface circuit 25 (.) To the control input 4 (., 2) of the associated control circuit 4 (.).

Switching device 45 is controlled by a code detector 47. It is provided with a data input 47 (1) which is connected to the output 24 (2) of the switching device 21 (2). It is also provided with a clock input 47 (2) which is connected to the output 24 (3) of the switching device 21 (3). This code detector 47 is designed to detect, for example, four code words, namely three address codes A, B and C and the stop sign D. More particularly, when the stop sign is received, the switching device 45 is brought into the rest position. This rest position is symbolized by connecting the input 45 (1) of the switching device to the rest output 45 (2). If address code A is received, the input of the switching device 45 is connected to the signal output 46 (1), upon receipt of address code B this input is connected to the signal output 46 (2), while upon receipt of address code C the input 45 (1 ) is connected to the signal output 46 (3).

As can be seen from Figure 6, the control circuit shown therein has the great advantage that the peak value detector 18 does not now have to be deactivated if the control signals are digital. After all, no digital control signal needs to be fed to the connecting pin 5 (1). Therefore, capacitor 17 can now remain permanently connected to terminal pin 5 (1).

Code detector 47 can be configured as shown in FIG. 7 is shown schematically. It contains a shift register 48 where the bits that occur at the input 47 (1) are written and shifted under the control of the clock pulses that occur at the clock input 47 (2). Four comparison circuits 49 (.) Are connected to this shift register 48. On the one hand, a comparison address code A, B, C, D is applied, each of which is stored in a memory 50 (.). If the content of the shift register 48 corresponds to a comparison address code, the corresponding comparison circuit supplies an output signal which connects the input 45 (1) of switching device 45 to that output 45 (2) or 46 (.) Corresponding to this address code.

10 D (5). Concluding remarks a) As already shown In the exemplary embodiment of figure 6, also the switching devices 21 (.) Used in the control circuit shown in figure 2 can all be controlled by one and the same detection circuit, e.g. detection circuit 20 ( 2).

b) In the foregoing, it has been tacitly assumed that the counting circuit 40 used in the interface circuit 25 (.) is constituted by a modulo N counter. However, a two-way counter with an addition input and a countdown input can also be used for this.

When such a counting circuit is used in the control circuit shown in Figure 6, the switching device 45 must be configured so that for each two-way direction counter it has one output connected to the cp count input and one output which is connected to the countdown input, these outputs being separately addressable.

30 35 8201613

Claims (9)

Control circuit for setting at least one adjustable quantity of an information signal, comprising: a) at least one control circuit which comprises an information signal input for receiving an analog information signal 5 and which is provided with a control input; b) means for receiving a control signal; c) first means for coupling the control input of the control circuit to the control signal receiving means; characterized in that d) a detection circuit is provided which is connected to the control signal receiving means and which produces an indication signal representative of the nature (analog or digital) of the control signal; e) said first means comprise first switching means which are controlled by the indication signal and which are provided with e.1. an input connected to the control signal receiving means; e.2. a first output connected to the control input of the control circuit; e.3. a second exit; f) second means for coupling the second output of the first switching means to the control input of the control circuit. Control circuit according to claim 1, characterized in that said second means comprise a cascade circuit of a memory and a digital-analog converter. Control circuit according to claim 2, characterized in that the memory is formed by a digital counting circuit. Control circuit according to claim 1, characterized in that between the cascade circuit and the second output of the first switching means, second switching means are arranged, which are controlled by the output signal of an address decoder, the input of which is coupled to the control signal receiving means. Control circuit according to claim 4, characterized in that the second switching means are provided with two or more outputs, each of which is connected with a cascade circuit of a memory and a digital-analog converter, while of each cascade 8201613 EHN 10.327 12, The output is connected to the control input of an associated control circuit. Control circuit according to claim 1, characterized in that the detection circuit is formed by a level detector. g Control circuit according to claim 1, characterized in that the control signal receiving means is connected to a control signal source which is formed by a potentiometer circuit which supplies an output signal whose level is in a first range: Control circuit according to claim 2, characterized in that the control signal receiving means is connected to a control signal source which is formed by a digital signal source which supplies an output signal consisting of a sequence of "0" and "1" pulses whose levels are located in a second range. Control circuit according to claim 8, characterized in that the control signal source comprises a microprocessor which supplies an address code at its output followed by a number of information bits. 20 25 30 35 8201613