RU2292126C2 - Method for automatic adjustment of radio-electronic device and automatic adjuster - Google Patents

Abstract

FIELD: radio engineering and technical cybernetics.

SUBSTANCE: concept, upon which automatic adjustment method is based, assumes that user after manually adjusting a radio-electronic device records adjustments under name, appropriate for signal, in which adjustments took place, and on repeated receipt of this signal it is recognized and adjustment are read from memory automatically. For realization of idea automatic adjuster contains controlled block, signal recognition block, memory block and control code generator.

EFFECT: possible automatic adjustment of electronic device in accordance to certain requirements of user and without addition of special information about adjustments to useful input signal.

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Description

The invention relates to the field of radio engineering and technical cybernetics and can be used in the construction of electronic devices (REU) with automatic tuning, the control process of which takes into account the features of the input signals.

By tuning the electronic device should mean a deliberate change in the parameters of the REU, necessary to obtain the desired output signal (expected, desired result). The setting can be manual, automatic and, if necessary, combined. Each of these approaches has been known for many decades and is widely used in devices of various purposes: from large radio navigation systems to household radios.

The simplest and most common way to automatically adjust the REU is automatic gain control, the essence of which is to constantly monitor the amplitude of the input signal and change the gain of the working path when the amplitude exceeds a certain threshold value [Pervachev S.V. Radio Automation. - M .: Radio and communications, 1982, pp. 39-42]. In fact, automatic gain control is used to stabilize the output voltage while preserving informative components, moreover, stabilization occurs according to the same rule for all signals in accordance with a constant adjustment characteristic. This principle of control of the REU significantly limits the capabilities of automatic tuning systems.

A method of automatic tuning of the REU (prototype) is rather effective, consisting in the fact that information on the necessary settings of the REU is preliminarily added to the useful input signal, when such a signal arrives at the input of the REU, information about the settings from the signal is extracted and then used to generate control signals that change device parameters [British Patent No. 2280340, 1994, G 11 B 20/00, H 03 G 5/16]. In the aforementioned patent, the method is used to automatically control the timbre of music programs. The basis of the automatic controller that implements this method is a controlled unit and a memory unit.

The prototype method allows you to automatically configure the REU in an arbitrary way according to the information contained in the signal. But at the same time, a significant drawback of the method is the need to add special information about the settings to the useful signal, which severely limits the scope of the method. Another disadvantage of this method is the impossibility of automatically setting the REU settings in accordance with the specific requirements of the user, since the information about the settings is already contained in the signal itself, and the user does not affect its contents in any way.

The technical result achieved when using this group of inventions is to enable automatic tuning of the REU in accordance with the specific requirements of the user and without adding special information about the settings to the useful signal.

The technical result is achieved by the fact that according to the method of automatic tuning of a radio electronic device according to the invention, the device is initially tuned manually based on specific requirements corresponding to a particular input signal and based on the receipt of a specific result, the settings obtained are stored as corresponding to a given signal characterized by one or more recognition features, further in automatic mode, when an input signal appears, it is recognized, after which it is extracted The corresponding settings are deleted from the memory.

In the claimed method, the setting can be performed according to one parameter or simultaneously according to several parameters, either by changing the characteristic of the electronic device, or by changing several characteristics of the electronic device at the same time.

In the inventive method, the signal can be recognized by its amplitude, or by its frequency, or by its average value, or by the average value in the selected frequency band, or by its average-rectified value, or by the average-rectified value in the selected frequency band, or by its rms value or by the rms value in the selected frequency band, or by its dispersion, or by its spectrum, or by the time of its appearance, or by its index, or by the nature of the information contained in it, or several im featured recognition.

To achieve a technical result, an automatic controller that implements a controlled unit and a memory unit according to the invention further comprises an input signal recognition unit and a control code adjuster, the controlled unit directly serves to configure the electronic device, the input and output of the controlled unit respectively serve as signal input and output controller, a memory unit is designed to record and store information about the settings, the control code dial serves to initially Manual tuning of the electronic device and setting control signals for the controlled unit.

In the claimed controller, the controllable unit can be made in the form of a device with a manageable complex transfer coefficient or the controllable unit can be used to control the timbre of the audio signal or to control both the timbre and volume of the audio signal, or to control the nature of musical images in a multi-channel audio path.

The input signal recognition unit, intended for use in the claimed controller, according to the invention consists of a recognition feature extraction unit, a recognition feature evaluation unit and an output code converter, the output of which is an output of the input signal recognition unit, the input of which is the recognition feature allocation unit, the output of which connected to the input of the recognition attribute evaluation unit, the output of which is connected to the input of the output code converter.

The invention is illustrated graphic material.

Figure 1 shows a functional diagram of an automatic controller; figure 2 shows a block diagram of an automatic tuning algorithm; Figures 3-5 show functional diagrams of various embodiments of an input signal recognition unit; 6 shows a functional diagram of an audio amplifier in which an automatic controller is used; figure 7 shows a functional diagram of a multi-channel audio path, which uses an automatic controller; on Fig shows a functional diagram of an automatic tone control, including the signal source and amplifier path; figure 9 shows a functional diagram of a controlled timbral unit connected to a memory unit.

The controller circuit of FIG. 1 comprises a controlled unit 1, a signal recognition unit 2, a memory unit 3, and a control code setter 4. The information input and output of the controlled unit 1 serve as a signal input and output of the controller, the input of the recognition unit 2, the signal is connected to the input of the controller, the output of unit 2 is connected to the address input A of memory unit 3, whose bi-directional data bus DB is connected to the control bus of unit 1, to the specified bus is also connected to the output of the master 4 control code. The PR input of the programming unit 3 memory serves as a control input for storing settings.

The flowchart of FIG. 2 shows the sequence of basic operations in two cases: when settings are not required and when the user sets the REU for a specific signal.

The circuit of FIG. 3 contains a recognition feature extraction unit 5, a recognition feature evaluation unit 6, and an output code converter 7, the output of which is the output of the signal recognition unit, the input of which is the input of block 5, the output of which is connected to the input of block 6, the output of which is connected to converter input 7.

The circuit of FIG. 4 contains a high-pass filter 8, a mean-rectified value meter 9 and an address code converter 10, the output of which serves as the output of the signal recognition unit, the input of which is the input of the filter 8, the output of which is connected to the input of the meter 9, the output of which is connected to the input transducer 10.

The circuit of FIG. 5 contains a spectrum analyzer 11, a unit 12 for comparing the level of spectral components, a converter 13 to an address code, the output of which serves as the output of the signal recognition unit, the input of which is the input of the spectrum analyzer 11, the output of which is connected to the input of the block 12, the output of which is connected to the input transducer 13.

The circuit of FIG. 6 contains a preamplifier 14, an automatic controller 15, a terminal amplifier (power amplifier) and an acoustic system 17, the input of which is connected to the output of the terminal amplifier 16, the input of which is connected to the output of the automatic controller 15, the input of which is connected to the output of the preamplifier 14, the input of which is the input of an audio amplifier.

The circuit of Fig. 7 contains a signal source 18, an automatic controller 19, a multi-channel audio amplifier 20 and a group of 21 speaker systems that are connected to the corresponding outputs of the amplifier 20, the input of which is connected to the output of the automatic controller 19, the input of which is connected to the output of the signal source 18.

The circuit of Fig. 8 contains a signal source 22 — a CD player, a controlled tone block 23, a memory unit 24, an amplifier 25, an acoustic system 26. The audio signal output of the source 22 is connected to the audio input of the controlled tone block 23, the audio output of the controlled tone block 23 is the audio output of the automatic tone control . The address input A of the memory unit 24 is connected to the output of the subcode of the signal source 22, the bi-directional data bus DB of the memory unit 24 is connected to the control bus of the controlled tone 23, the programming PR input of the memory 24 serves as the control input of the automatic tone control. The memory unit 24 is represented as a reprogrammable read-only memory device with electrical rewriting of information. The output of the tone block 23 is connected to the input of the amplifier 25 with a load of 26.

The circuit of FIG. 9 consists of a two-band controlled tone block 23 and a memory block 24. In turn, the tone block 23 contains a controllable high-pass filter 27, a controllable low-pass filter 28, an adder 29, code converters 30, 31 to filter control signals, control code switches 32, 33. The inputs of the filters 27, 28 are combined and make up the input of the audio signal, the outputs of the filters 27, 28 are connected to the inputs of the adder 29, the control input of the filter 28 is connected to the output of the converter 30, the input of which is connected to the output of the setter 32, the control input of the filter 27 is connected to the output of the converter 31, the input of which is connected to the output of the master 33, the enable inputs OE of the master 32, 33 are combined with the input OE (output enable) of the memory unit 24 and form the enable input E of the controlled timbral block to the bi-directional information bus DB of the memory unit 24 outputs connected setting devices 32, 33 code; A - the address input of the memory unit 24 is used to select memory cells in which the settings of the tone block are recorded and where these settings are stored; PR - input programming unit 24 memory. The code dial 32 is used to set the low-frequency control code of the signal supplied to the audio input, and dial 33 is used to set the high-frequency control code.

The concept underlying the automatic tuning method is that after manual tuning of the electronic device, the user remembers the settings under the name corresponding to the signal at which the settings were made, and when this signal reappears, it is recognized and settings are automatically retrieved from the memory.

To illustrate the method, we turn to the circuit of the automatic controller (figure 1). Suppose that the controlled unit 1 is designed to introduce changes in the complex transfer coefficient K (jω) = K (ω) e ^jΔφ (ω is the circular frequency; Δφ is the phase shift) by changing its modulus K (ω). This is a well-known task of controlling the amplitude-frequency characteristic of a REU. Thus, in this case, the setting of the REU is considered to be the selection of the quantity K (ω). Using the adjuster 4 of the control code, the value of K (ω) is manually changed, and the changes made can be estimated in any way that the task implies, for example, visually from the readings of the instruments or by ear. After using the controlled unit 1 the necessary changes have been made to the parameter K (ω), it must be remembered. Moreover, it is advisable to remember not the value of K (ω) itself, but the control code corresponding to the parameter obtained as a result of tuning, that is, some functional F [K (ω)]. To memorize a code that carries information about the settings, a memory block 3 is used, the information input of which is sent via a bidirectional DB bus from the code setter 4 and a control code is supplied. The specified code is recorded at the address that is specified by the input signal itself, characterized by one or more recognition features. Let in our example, the recognition sign is the level of high-frequency components in the spectrum of the input signal. This means that block 2 must select high-frequency components and evaluate their level (see figure 4). The recognition result is an output code that serves to address block 3 - the address code received at input A of block 3 of the memory. The control code is written to block 3 using the PR programming signal. The same signal completes the manual configuration step presented on the left side of the flowchart (Fig. 2).

Remembering the control code corresponding to a specific signal for which specific settings are made should be regarded as creating a connection of settings with one or more characteristic features (recognition signs) of the input signal.

From the above example, it can be seen that at the manual tuning stage, three basic operations are performed: manual tuning using the code setter 4; storing settings in memory block 3; creating a connection of settings with a pre-selected sign (s) of recognition of the input signal, for which the combination of recognition blocks and memory serves.

The automatic controller under consideration (Fig. 1) belongs to the class of trained systems, and the above operations are integral components of its functioning algorithm. For the regulator to operate in automatic mode, it undergoes a preliminary training procedure, consisting in presenting to the regulator a set of input signals with the obligatory indication of specific settings, which each of the presented signals should relate to. The totality of such signals is a training sample, of course, of a finite volume. However, in the automatic tuning mode, the input signals can be not only copies of the signals from the training set, but also any other signals, the assessment of recognition signs of which coincide with the ratings of the recognition signs of signals from the training set. Moreover, by coincidence in this case we can also mean that values fall into a certain region, subset, and the number of such regions or subsets is the number of recognized signals — the number of possible settings. For example, if we are talking about the level of high-frequency components in the spectrum of the input signal and if a signal with a high-frequency level S ₁ was presented during training, then when automatically tuning, all signals with a level of high-frequency components lying in the range (S ₁ -ΔS) ... (S ₁ + ΔS). In this case, ΔS is a value that determines the size of the range and is determined both by the total number of recognized signals and by the specific requirements for the automatic controller.

In the automatic tuning mode (the right part of the flowchart of FIG. 2), the signal received at the input of the controller (FIG. 1) is recognized, and the settings stored in the form are saved from the memory using the recognition results (the set into which it belongs) control code of block 1. (Despite the fact that the main mode of operation of block 3 of the memory at this stage is to read information, one should not exclude the possibility of updating information in case of abandonment of the old settings.)

The structure of the controlled unit 1 is selected depending on the settings according to what parameters or characteristics of the REU it is intended. In this example, block 1 serves to change the value of K (ω) (frequency-dependent gain) and can be a controlled amplitude-frequency corrector (equalizer, two-band timbral block, etc.). In the General case, the managed unit 1 should be able to change one or more parameters of the REU, which are configured, under the influence of external control signals. The same requirements apply to the controlled unit in the event that the adjustment is made by changing the characteristics of the REU. Regarding the control code setter 4, we note that in essence it is a control input block and is built in conjunction with block 1 taking into account its features and specific purpose. If block 1 is controlled by a binary code, then setter 4 must also be an external manual block for generating binary codes. And of course, there must be a strict functional relationship between control codes and variable parameters (characteristic), for example, linear.

The recognition process boils down to two main actions: the selection of the recognition feature and its evaluation (figure 3). Depending on the selected recognition attribute, a block 5 for distinguishing the recognition attribute is constructed. For example, if the recognition level is a high-frequency level, then a high-pass filter can be used as block 5 (Fig. 4). In the same example, as the block 6 of the evaluation of the characteristic used meter 9 of the average straightened value. As for the converter 7 of the output code, its purpose is to present the result of the evaluation of the recognition attribute in a form convenient for controlling the address sector of the memory block 3. If you are using a memory unit with a classic digital address control using binary code, then as a Converter 7 should use the Converter in a binary address code.

In the example shown in FIG. 5, the recognition unit is used to recognize signals by the shape of the spectrum. Spectrum recognition of signals can be useful in tasks of automatic precision adjustment of tonal balance in audio paths.

The automatic controller in applied problems of sound reproduction can be switched on both between the preliminary and final amplifier (Fig.6), and between the signal source and subsequent blocks (Fig.7). The latter case is additionally illustrated by the use of an automatic control to adjust the sound timbre of a signal recorded on a CD (Fig. 8).

The principle of operation of the automatic tone control (Fig) is as follows.

A CD player 22 is adopted as a signal source, providing both an audio signal and service information contained in a subcode of a compact disc, where the disc name may also be located. The disk name code, which plays the role of an individual characteristic (recognition feature) of the signalogram, is sent to the address input A of the memory unit 24 and calls the memory cells corresponding to this code. The listener, being in the listening area, manually controlling the timbre block 23, changes the sound timbre amplified by the amplifier 25 and emitted by the speaker 26. After setting the desired timbre, the listener sends a PR command (programming signal) to remember the settings at the previously called address in the memory unit 24. Thus, a connection is established between the individual settings and the signalogram. When the signalogram is repeated, the information contained in the subcode is fed to the address input of block 24 and recalls the previously recorded settings in the form of control codes for the timbral block 23. Thus, the sound tone is automatically set in accordance with the specific requirements of the listener and corresponding to a specific signal.

The principle of interaction of the controlled timbral block with the memory unit in the claimed automatic tone control is illustrated by a functional diagram (Fig. 9) containing a two-band electronic control timbral block. Low-frequency control is performed by setting and changing a control code using a code setter 32, and high-frequency control is performed using a setter 33. The control codes are transmitted through the converters 30, 31 to the control inputs of the filters 28, 27, which serve for a controlled change in amplitude -frequency characteristics of the sound path. The codes are set, that is, manual adjustment of the tone, occurs at E = 1 - with enable levels at the inputs of the OE sets 32, 33 and a inhibitory level OE of the memory unit 24. The latter at E = 1 should only work on receiving information on the bi-directional DB bus. At the end of the settings, the setting codes set at outputs 32, 33 are written to the memory unit 24 by the PR programming signal. When re-playing the signal for automatic tuning to the input E, you should apply a logic zero level. In this case, the setters 32, 33 are disconnected from the information buses, turning into a high-impedance state at the outputs, and the bi-directional DB bus goes into a state corresponding to the transmission of information from the output of the memory unit 24 to the inputs of the converters 30, 31. (It should be clear to the reader that and code adjusters 32, 33, and block 24 should be able to translate their outputs into a third illogical state under the influence of OE signals).

Claims (20)

1. A method for automatically tuning a radio electronic device, characterized in that the radio electronic device is initially tuned manually, based on specific requirements corresponding to a particular input signal and based on obtaining a specific result by selecting at least one variable parameter of the electronic device, then by a programming signal remember the control code corresponding to the parameter obtained as a result of manual adjustment, create a connection with the settings in advance scolded by at least one sign of recognition of the input signal, then automatically when the input signal corresponding to the setting appears, the specified signal is recognized by highlighting the recognition sign and its evaluation, and then the settings corresponding to the specified signal are extracted from the memory. 2. The method according to claim 1, characterized in that the signal is recognized by its amplitude. 3. The method according to claim 1, characterized in that the signal is recognized by its frequency. 4. The method according to claim 1, characterized in that the signal is recognized by its average value. 5. The method according to claim 1, characterized in that the signal is recognized by the average value in the selected frequency band. 6. The method according to claim 1, characterized in that the signal is recognized by its average straightened value. 7. The method according to claim 1, characterized in that the signal is recognized by the average straightened value in the allocated frequency band. 8. The method according to claim 1, characterized in that the signal is recognized by its rms value. 9. The method according to claim 1, characterized in that the signal is recognized by the rms value in the selected frequency band. 10. The method according to claim 1, characterized in that the signal is recognized by its dispersion. 11. The method according to claim 1, characterized in that the signal is recognized by its spectrum. 12. The method according to claim 1, characterized in that the signal is recognized by the time of its appearance. 13. The method according to claim 1, characterized in that the signal is recognized by its index. 14. The method according to claim 1, characterized in that the signal is recognized by the nature of the information contained therein. 15. The automatic controller that implements the method according to claim 1, comprising a controllable unit and a memory unit, characterized in that an input signal recognition unit and a control code adjuster are inserted in it, the controllable unit serves directly to configure the electronic device, the input and output of the controllable unit serve Accordingly, with the signal input and output of the controller, the memory unit is designed to record and store information about the settings, the control code setter serves for the initial manual tuning of the electronic troystva and setting control signals for the controllable unit, the recognition unit input signal is connected to the input of the regulator, the output detection unit is coupled to the address input of the storage unit, a bidirectional data bus which is connected to the control bus managed unit to said bus connected also to the output set point control code. 16. The controller according to claim 20, characterized in that the controlled unit is made in the form of a device with a controlled integrated transmission coefficient. 17. The controller according to claim 20, characterized in that the controlled unit is designed to control the sound of the audio signal. 18. The controller according to claim 20, characterized in that the controlled unit is designed to control both the timbre and the sound volume of the audio signal. 19. The controller according to claim 20, characterized in that the controlled unit is designed to control the nature of musical images in a multi-channel sound reproducing path. 20. The input signal recognition unit, intended for use in the controller according to claim 15, characterized in that it consists of a recognition feature extraction unit, a recognition attribute evaluation unit and an output code to address code converter, the output of which serves as the output of the input signal recognition unit, input which serves as the input of the recognition feature extraction unit, the output of which is connected to the input of the recognition feature evaluation unit, the output of which is connected to the input of the converter of the output code to the address code.

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