CS199640B2 - Stable meter of peak level of audio frequency signals with discrete indication - Google Patents

Description

The invention relates to a stable peak-level meter of tone-frequency signals with a discrete indication which allows high-precision peak-level measurements with low current fluctuations and with a scale of considerable resolution as well as a strong over-modulation indication; the instrument can be used especially as a level indicator in studio technology.

In a remote transmission technique, in particular a low frequency technique, the intensity, amplitude and peak value of the information converted to electrical signals is measured by means of a signal level indicating device. Signal level indicating devices usually consist - in order of their function - of the following components: adaptive amplifier - peak rectifier - logarithmic circuit - dc amplifier - circuit for setting the in-and-out constant and the electrical measuring device. Such signal level indicating devices are already known, but there are always instabilities and inaccuracies in the measurement. The source of these errors can be seen in the rectification of low-level signals, in logarithms, in DC amplifiers and in measuring instruments.

The logarithm is accomplished by supplying an incoming, rectified signal level to a current or voltage distribution circuit, providing a signal distribution depending on its level. In order to achieve a good approximation of the logarithmic curve, it is necessary that the level-dependent distribution be highly accurate. However, this is difficult to achieve due to the temperature dependence of the transistors or diodes used.

It is known that rectifiers and DC amplifiers do not work perfectly at lower levels, and that precise operation can only be achieved by a complex design. Since the level indicator device must reliably register even a thousandth of the maximum level of the measured signal, it is clear that conventional devices exhibit a significant number of errors.

For level indication devices, emphasis shall be given to the fact that step-changing information is faithfully recorded; For this reason, high demands are also placed on measuring instruments. The ideal electrical measuring instrument does not exist at all, since it is necessary to count with oscillating mass. Although there are complex devices that allow the rise time and overshoot to some extent to be reduced, for example, a luminous indicating device: a device with an appropriate optical system, but such devices can be easily damaged due to their complexity. With modern paneling panels, u199640 is currently desirable

199840 to position more immediately next to each other at a distance of 20–25 mm. However, such an arrangement is not feasible in conventional electrical measuring instruments due to the interaction of the permanent magnets and also with regard to the space required.

As can be seen from the above, the requirements of modern studio technology cannot satisfy conventional level indication devices. The use of analogue-digital indication has proved to be useful for measuring modulation. Instead of the continuous, i.e. analogue, indication, a digital display consisting of a series of light-emitting diodes with an appropriate resolution was used. Indeed, such measuring instruments can be free from errors of conventional level indication devices. Their construction in the order of function of their individual units looks like this: adaptation stage - peak rectifier - a series of logarithmic comparators with a reference distribution circuit - indicating device with light-emitting diodes. It can be seen that the logarithm provides a simple resistor chain and that there is no temperature-dependent element. The setting up and down times are carried out purely electronically, since the displays with light-emitting diodes do not show any mechanical moment of inertia. Due to the non-linearity, the rectification of small-level signals is only ensured to some extent.

A disadvantage of these level indication devices is the fact that the current consumption is proportional to the number of simultaneously emitting light emitting diodes. The accuracy of such devices is additionally affected by the scale resolution, i.e. the number of light emitting diodes used. With a resolution of the scale corresponding to 26 light-emitting diodes, the current variation between the modulated, unmodulated state can be up to 26 times. As a result, when used with control studio panels, other parameters suffer or a special stabilization filter needs to be installed. For this reason, it is expedient to reduce current fluctuations to the smallest possible value.

A further disadvantage of said devices is that there is no significant overmodulation warning indication. For conventional level indicators, such as a light indicator instrument, the indicator screen is in the white mixing range, but red in the overmodulation range. Here it can be stated that the warning indication is sufficient. For an indicator with light-emitting diodes - since only the red color is sufficiently strong - light-emitting diodes of the same color must be extended and fitted with a square mask in the transverse direction. The disadvantage of this solution is that the luminous intensity is reduced because the light-emitting surface is narrowed; however, the distance between the light-emitting diodes increases and their eyes flash due to fatigue.

Taking into account what has been said above, a modern level meter is intended to meet the following requirements:

Highly accurate measurement in both small and large range.

2) Low current consumption, avent. Low power consumption fluctuation.

3) A strong indication of overmodulation.

Disadvantages of the known devices can be eliminated and the above-mentioned requirements can be satisfied by a stable meter of discrete indication tone frequency signals according to the invention, which consists in that the sorting stage has two outputs, of which the high-level output of the sorting stage is connected to the high-level peak rectifier input. via a high-level adjustment stage connected to the input of the first row of comparator circuits, and further the low-level output of the sorting stage is coupled to the input of a low level or peak rectifier connected via the low-level adjustment stage to the input of the second row of comparator circuits. with inputs of a series of switching circuits, the output of which is connected to the input of a number of luminescent diodes.

It is further an object of the invention that the outputs of the first and second series _; the comparator circuits are connected to the control input of at least two controlled switch circuits, the first output of the first row of comparator circuits being connected to the control input of the third switching circuit, to the second input of which the first output of the second row of comparator circuits is connected. the second switching circuit input, the other output of the second series of comparing circuits is connected to the second input of the second switching circuit and by common connection to the control input of the first switching circuit and yet another output of the second series of comparing circuits is connected to the second input of the first switching circuit a circuit of a luminescent diode, for example a third group of luminescent diodes, is connected, the output of the third circuit being connected to a circuit, a second switching circuit and a third switching circuit. one end of the luminescent diode serial circuit, the other end of which is grounded, and in the luminescent diode serial circuit, the output of the second switching circuit is connected to the junction of the third luminescent diode and the second luminescent diode and the first luminescent diode serial circuit.

It is also an object of the invention that the series of switching circuits is composed of at least two groups, the first group of switching circuits comprising at least one switching circuit, the first output of the second series of comparative circuits being connected to one input of the third switching circuit; the first output of the first series of comparing circuits is connected to the input of the second switching circuit of the first group of switching circuits, the second output of the first series of switching circuits is connected to the control input of the second switching circuit of the first group of switching circuits a first switching circuit of a first group of switching circuits and a control input of a second switching circuit group, wherein a second output of a second series of comparing circuits is connected to a second input of the second switching circuit group, controlling an input of a first switching circuit p The first group of switching circuits is connected to its output, which is connected to one terminal of the first luminescent diode of the first group of luminescent diodes, while its second terminal, connected to one terminal of the second luminescent diode of the first group of luminescent diodes, the output of the second group of switching circuits is connected to the input of the second group of luminescent diodes and the output of the third group of switching circuits is connected to the input of the third group of luminescent diodes.

The invention is explained in detail with reference to the accompanying drawings, in which Fig. 1 shows a diagram of an exemplary embodiment of a level indicator, Fig. 2 shows a part of the connection of Fig. 1 and Fig. 3 another part of the connection of Fig. 1.

Fig. 1 shows an exemplary embodiment of a level indicator implemented in accordance with the invention; the level indicator is constructed as follows: The input of the adaptation stage 1 is connected to an external signal level source and its output to the input of the sorting stage. 2. The two-level sorting stage 2 is connected by a high-level output A to a high-level precision rectifier 3 input and a low-level output B to a second precision low-level rectifier 4 input. The output of the precision high-level rectifier 3 is connected to the input of the high-level adjusting stage 5 for adjusting the inlet and outlet time constant, while the output of the precision high-level rectifier 4 'is connected to the input of the adjusting stage 6 . The output of the setting stage 5 is connected to the input of comparator series 7 and the output of the setting stage 8 to the input of another series of comparators 8. The output of the series of comparators 8 is connected to the input of a series of controlled current switching circuits 9.

10.

Adjustment stage 1 provides amplitude adjustment of the signal level applied to its input and suppresses interfering signals. Sorting stage 2 determines the level of the signal applied to its input and separates the high and low levels, thereby creating two classes of signals, which are then amplified separately so that the maximum amplitude of the low level signal is equal to the amplitude of the high level signal. The high-level signals as well as the low-level signals, which also have a high amplitude, are then fed to the precision peak rectifiers 3 and 4, wherein the precise peak rectifier 4 only directs signals of relatively high amplitude.

This part of the wiring fulfills the first requirement mentioned above. The control DC voltages of the comparator series 7 and 8, which are provided with a logarithmic reference splitter, are generated behind the precise peak rectifiers 3 and 4, in the already known adjustment stages 5 and 6. The output signals of the comparator series 7 and 8 control the current series switching. A series of light-emitting diodes 10 is controlled by their output signal. The wiring of a series of current switching circuits 9 and a series of light-emitting diodes 10 will be described below. The controlled series of current switching circuits as well as the series of light emitting diodes are divided into several groups comprising multiple controlled current switching circuits and light emitting diodes. The groups of light-emitting diodes are connected in parallel; within each group, the light emitting diodes are connected in series. With this arrangement, the current consumption within one group can be equal to the current consumption of one diode, regardless of whether only one or all light-emitting diodes are lit within that group. The current consumption or the current consumption fluctuation of the level indicator constructed in this way depends exclusively on the number of groups. For example, if thirty light emitting diodes are made up of five groups, i.e. six diodes, then the maximum possible current draw will correspond to the current draw of one single light emitting diode. FIG. 2 shows a group of light-emitting diodes comprising three groups of controlled current switching circuits and three light-emitting diodes.

In the construction of FIG. 2, a control signal C is supplied from the output of the comparator group 8 to the input of the controlled current switching circuit 931 of the switch circuit group 93; the output of said current switching circuit 931 is connected to a common junction point of light emitting diodes 1031, 1032, which are connected in series in the group of light emitting diodes 103; one terminal of the light emitting diode 1031 is connected to the supply voltage zero point.

A control signal D is applied to one input of the current switching circuit 932 having two inputs, and to the other, i.e., the control input D of the controlled current switching circuit 931 connected to the current circuit 932, is outputted. A control signal is provided to one input of the controlled current switching circuit 933 and to the other control input of the connected current switching circuit 932. The output of the controlled current switching circuit 933 is coupled to the second pole of the light emitting diode 1033, and its control input receives a control signal F from the output of the respective comparator of the comparator group 7.

The circuit shown in Fig. 2 works as follows:

The control signals C, D, E and F supplied by known comparator circuits have two voltage states which are determined by whether the respective comparator circuits are in the idle or operating position; in the first case the voltage of the supplied signal is zero, while in the second case the voltage corresponds to the + and - pole of the power supply. The control signals acquire a voltage -j- or vice versa in accordance with their order. If the control signal voltage is zero, the controlled current switching circuits 931, 932 and 933 will be blocked and there will be no control voltage on the light emitting diodes 1031, 1032, and 1033. As soon as the voltage of the control signal C becomes positive, the controlled current switching circuit 931 opens as a result of the voltage; this will cause the current to flow through the light emitting diode 1031 and the diode will light up. If the voltage of the control signal D also increases to a positive value, the control circuit 932 opens and at the same time the control circuit 931 closes; however, the control signal D through the current switching circuit 932, however, gives rise to a current flow through the serially connected light-emitting diodes 1032 and 1031, which light up. If the voltage of the control signal E also rises to a positive value, the current switching circuit 933 is opened by its action; at the same time, however, the current circuit 932 also closes and all series-connected light emitting diodes 1033, 1032, and 1031 light up. The control signal voltage F also becomes positive, the controlled current switching circuit 933 closes, the light-emitting diodes 1033, 1032 and 1031 no current flows and the diodes go out.

As can be seen from the foregoing, the described arrangement achieves that, when several light emitting diodes are lit simultaneously, their current consumption does not increase and that the light emitting diodes are extinguished even when the comparator circuits are flipped to the operating position. This satisfies both the first and third requirements (see also Fig. 3).

FIG. 3 shows an arrangement of a level meter indicating portion in which the rows of current switching circuits 9 and rows of light emitting diodes 10 are divided into three groups, one pertaining to the over-modulation range and comprising two current switching circuits and two light-emitting diodes. According to FIG. 3, the control signal E is applied to the input of the group of current switching circuits 93 of the controlled series of current switching circuits. The output of this group of current switching circuits is coupled to the input of the group of light emitting diodes 103 of the series of light emitting diodes 10. The control signal H is supplied to the input of the controlled group of current switching circuits 92; the output of this group is connected to the input of the light emitting diode group 102. The control signal F is applied to the input of the current switching circuit 912 of the group 91 and at the same time to the control input of the current switching circuit group 93. diodes 1011 and 1012 of the light emitting diode group 101; the light emitting diode 1012 is coupled to a zero power supply voltage. The control signal G is applied to the input of the controlled current switching circuit 911, the control input of the controlled group of the current switching circuits 92 and the control input of the controlled current switching circuit 912. The output of the controlled current switching circuit is connected to its own control input and to the other light emitting diode 1011. .

If the voltage of the control signals E, H, F and G is zero, the controlled series of current switching circuits 9 are closed and the series of light emitting diodes 10 are not lit. If the voltage of the control signal E becomes positive while the voltage of the control signals H, G and F is zero, then a group of light emitting diodes 103 lights up over the controlled group of current switching circuits 93; see also the arrangement in FIG. 2. If the voltage of the control signal H also becomes positive, the light emitting diode group 102 lights up over the controlled current switching circuit group 92, wherein the internal configuration of the controlled current switching circuit group 92 and the light emitting diode group 102 corresponds to the design. a group of current switching circuits 93 and light emitting diodes 103 of FIG. 2.

The voltage of the control signals F and G is only positive if the modulation range is to work; within this range the indication should be prominent. Thus, if the voltage of the control signal F is also positive, a controlled current circuit 912 is opened by applying this voltage, thereby illuminating the light emitting diode 1012; at the same time, the control group of the current switching circuits 93 is blocked and the light emitting diodes 103 are extinguished. In the case of major over-modulation, the control signal G delivers a positive voltage. Under this voltage, the controlled current switching circuit 911 is opened, but the second controlled current switching circuit 912 and the controlled group of current switching circuits 92 remain closed. This will light up the light emitting diodes 1011 and 1012, but the light emitting diode groups 102 and 103 will remain off.

With the illustrated arrangement, a distinct indication is reached on the do199640 meter when over-modulating, since as many light-emitting diodes light up, just as many light-emitting diode groups go out. In the case of maximum over-modulation, the entire field of the over-modulation range will be dark and only light-emitting diodes indicating light will be lit. The light of these diodes is then sufficiently striking and can be seen from a greater distance.

It can be seen that the described level meter allows very precise level control both in the measuring range pertaining to the low level and in the measuring range pertaining to the high level, which is achieved by splitting the signal into two or more rectifiers. The built-in and described arrangement of the controlled current switching circuits makes it possible to achieve low current consumption and small fluctuations in current consumption, even if the indication scale contains a number of light-emitting diodes. Controlled current switching circuits also enabled implementation of the described groups. By using n light-emitting diodes, or by switching them on and extinguishing with a period of time commensurate with the over-modulation, it is possible to obtain a strong indication of proper attention.

Claims (3)

PREDMfiT Fixed peak level meter of tone frequency signals with discrete indication, in particular for signal level indication in a studio, having an adaptation stage connected to an external voltage source, the output of the adaptation stage being connected to a sorting stage, characterized in that the sorting stage (2) ) is provided with two outputs, of which the high-level output (A) of the sorting stage (2) is connected to the input of the high-level peak rectifier (3), which is connected via the high-level adjusting stage (5) to the inputs of the first row of comparator circuits (7); further, the low-level output (B) of the sorting stage (2) is connected to the input of the low-level peak rectifier (4), which is connected via the low-level adjusting stage (6) to the input of the second series of comparator circuits (8); (7, 8) are connected to inputs of a series of switching circuits (9), the output of which is connected to an input of a series of luminescent diodes (10). Stable meter according to claim 1, characterized in that the outputs of the first and second series of comparator circuits (7, 8) are connected to the control input of at least two controlled switching circuits (9), the first output (F) of the first series of comparator circuits (7). 7) is connected to the control input of the third switching circuit (933), the second input of which is connected to the first output (E) of the second series of comparing circuits (8), which is connected to the control input of the second switching circuit (932) the other output (D) of the second series of comparator circuits (8) is connected to the second input of the second switching circuit (932) and, by common connection, to the control input of the first switching circuit (931); 8) is connected to the second input of the first switching circuit (931), to the outputs of the first switching circuit (931), the second switching circuit (932), and the third The third switching circuit (933) is connected to one end of the luminescent diode serial circuit, the other end of which is grounded, and in the serial circuit. the luminescent diodes output of the second switching circuit (932) to the junction of the third luminescent diode (1033) and the second luminescent diode (1032) of the serial luminescent diode circuit and the output of the first switching circuit (931) are connected to the junction of the second luminescent diode (1032) luminescent diodes (1031) of the luminescent diode serial circuit. Stable meter according to Claims 1 and 2, characterized in that the series of switching circuits (9) is composed of at least two groups, of which the first group of switching circuits (91) comprises at least one switching circuit (911, 912), one input of the third group of switching circuits (93) is connected to the first output (E) of the second series of comparing circuits (8), to the control input of the third group of switching circuits (93) is connected the first output (F) of the first series of comparing circuits (7) is connected 1 to the input of the second switching circuit (912) of the first group of switching circuits (91), to the control input of the second switching circuit (912) of the first group of switching circuits (91). connected to a second output (G) of a first series of comparator circuits (7), which is connected to an input of a first switching circuit (911) of a first group of switching circuits (91) and a control input of a second group of switching circuits (92); the second group of switching circuits (92) is connected to the second output (H) of the second series of comparator circuits (8), the control input of the first switching circuit (911) of the first group of switching circuits (91) is connected to its output which is connected to one terminal of the first luminescent diodes (1011) of the first group of luminescent diodes (101), while its second terminal connected to one terminal of the second luminescent diode (1012) of the first group of luminescent diodes (101) is connected to the output of a second switching circuit (912) of the first group of switching circuits (91), whereby 199840 the second terminal of the second luminescent diode (1012) of the first group of luminescent diodes (101) is grounded, the output of the second group of switching circuits (92) is connected to the input of the second group of luminescent diodes (102) and the output of the third group of switching circuits (93) input of a third group of luminescent diodes (103). 2 sheets of drawings