RU2787130C1 - Remote control - Google Patents

Abstract

FIELD: electronics.

SUBSTANCE: invention relates to the field of electronics, namely to means for remote control of household electronic devices. To achieve the effect, the remote control contains a microphone, a memory, a block for generating coded signals, including codes of pressed buttons, stored in the memory and providing remote switching of channels on an electronic device emitting a sound stream. At the same time, the remote control further comprises an automatic channel switching unit and an associated channel switching queue generator, which, in turn, has a means for inputting a predetermined sequence of codes of pressed buttons into it.

EFFECT: ensuring automatic selection of the channel preferred by the user when an undesirable repetitive sound appears on the electronic device controlled by the remote control.

7 cl, 16 dwg

Description

The invention relates to the field of electronics, namely to means of remote control of household electronic devices.

Currently, most modern electronic devices (TVs, radios, car radios, music centers) intended for use by their users at home have special remote controls that allow you to control the most important functions of these devices from a distance. One of them - channel switching - is often used not only for its intended purpose, but also when a repeated sound that is undesirable for the user appears, for example, in the form of various sound screensavers or recurring commercials.

From the prior art, many variants of remote controls are known, differing from each other in various improvements. One of them is described in US patent No. 5847305 and has the entire set of features that are characteristic of almost all such devices.

However, the latest versions of remotes often contain additional functions that are not related to the control of electronic devices. One of these analogs is described in US patent No. 8519820 and is made in the form of a smartphone with a function that allows, in particular, to save the settings of an electronic device controlled by a remote control for audio content previously transmitted by it.

In another analogue, described in US patent No. 10812903, an additional function is to automatically adjust the volume of the electronic device depending on the level of ambient noise.

A design feature of the last two analogs, which allows them to have an additional function - microphones built into their cases.

However, despite this, their disadvantage is the need to manually turn off the sound on electronic devices. This is in some cases extremely inconvenient for their users, since in order to turn off the annoying sound coming from, for example, frequently repeated commercials, they have to first find the remote control itself, and then the mute button.

At the same time, a device described in patent RU No. 2764675 is known, which does not have this drawback. This analog is a prototype of the claimed invention and is a remote control containing a microphone, a memory, a block for generating coded signals, including codes of pressed buttons stored in memory and providing remote switching of channels on an electronic device emitting a sound stream, as well as a block for determining parameters of sound radiation and the unit for generating a mute signal associated with it, containing a unit for comparing the current sound parameters with the parameters of sound fragments selected and recorded in memory by means of an on/off unit.

However, the disadvantage of this remote control is in many cases the inconvenience for the user of the electronic device that occurs after the automatic sound is turned off. The fact is that if a sound saver signaling the beginning of an inappropriate transmission for the user is adopted as a repeating sound, then the user has to manually select a channel to listen to other sound information. In another scenario of using the prototype, the user can also experience considerable discomfort due to prolonged audio pauses, which may appear due to sufficiently long commercials. After all, during such pauses, very important sound information for the user, broadcast on other channels often used by him, can be missed.

The problem to which the invention is directed is the creation of a remote control with automatic selection of the channel preferred by the user and when an undesirable repetitive sound appears for him.

The problem is solved due to the fact that the remote control containing a microphone, a memory, a block for generating coded signals, including codes of pressed buttons, stored in memory and providing remote switching of channels on an electronic device emitting a sound stream, as well as a block for determining parameters connected to the microphone sound radiation and an associated mute signal generation unit, containing a unit for comparing the current sound parameters with the parameters of sound fragments selected and stored in memory by means of an on/off unit, additionally contains an automatic channel switching unit and an associated channel switching queue generator, moreover the automatic channel switching unit is connected to the comparison unit and is designed to read the code of the pressed button from the channel switching queue generator at each appearance of a signal at the output of the comparison unit, and the queue generator The purpose of the channel switching function is to establish a predetermined sequence of the appearance of the codes of the pressed buttons each time a reading signal occurs from the automatic channel switching unit, while the automatic channel switching unit is connected to the coded signal generation unit, and the channel switching sequencer has a means for inputting a predetermined sequence into it codes of pressed buttons

The technical result of the invention consists in expanding the functionality of the remote control, which consists in providing automatic selection of the channel preferred by the user when an undesirable repetitive sound appears on the electronic device controlled by the remote control.

Other features and advantages of this invention will become clear from the detailed description, as well as from paragraphs 1-7 of the claims.

The invention is illustrated by the attached drawings, in which:

fig. 1 depicts a general view of the remote control and the TV;

fig. 2 depicts a general view of the remote control and the two electronic devices controlled by it;

fig. 3 is a diagram of a remote control;

fig. 4 is a diagram of an automatic channel switching unit;

fig. 5 shows a first variant of the functional diagram of the channel queuing generator;

fig. 6 shows a second version of the functional diagram of the channel queuing generator;

fig. 7 shows a third version of the functional diagram of the channel queuing generator;

fig. 8 shows a fourth version of the functional diagram of the channel queuing generator;

fig. 9 is a view of the first version of the remote control;

fig. 10 is a view of the second version of the remote control;

fig. 11 is a view of a graphical interface displayed on a touch screen of a smartphone;

fig. 12 is a view of the third version of the remote control;

fig. 13 is a diagram of an auxiliary control panel;

fig. 14 is a diagram of the on/off unit;

fig. 15 is a diagram of a channel sequencing algorithm;

fig. 16 is a diagram of the operation of the remote control.

In describing the best embodiments of this invention, and for the convenience of its further consideration, all abbreviations in brackets after one or more words will refer to their initial letters. In addition, all terms used in the description are either generally accepted in the scientific and technical literature, or are used in official sources.

In FIG. 1 shows the main means included in the system using remote control elements. Controlled by a remote control (RC) 1, an electronic device (EA) is made in the form of a TV 2, which has an infrared radiation receiver (IRR) 3 and an electroacoustic transducer (EC) 4. The latter creates a stream of sound radiation (SSI) 5, which is received by the RCU 1 s using a microphone located outside or inside the case 6. The latter also has a special compartment for installing a battery, which usually consists of two batteries. It can be noted that hereinafter under the remote control 1 we mean a device made according to this invention. If the text contains a remote control that is not related to the invention, then it will refer mainly to the standard remote control attached to the EA by its manufacturer, and have a different digital designation. The coded infrared radiation flux (CIR) 7 is generated by an emitter mounted on the front wall of the housing 6. Of the other elements of the remote control 1 shown in FIG. 1, it should be noted the special buttons "Selecting a sound fragment" 8, "Entering the order of switching on channels" 9, "Entering a user code" 10, the main keyboard (OK) 11, consisting of function buttons responsible for various TV settings 2 (switching channels, brightness adjustment, etc.), and an auxiliary display (AD) 12. The external difference between the standard remote control and the described device is the presence of buttons (Kn) 8, 9, 10 in it. This is done in order to avoid confusion when considering this description, so as in the practical implementation of the invention, the functions of each of these buttons can be activated by simultaneously pressing a known combination of the corresponding buttons on the standard remote control. Common settings for all electronic devices with ES 4 include switching channels, for example, during repeated advertising or unwanted audio information, intended, for example, only for adult users. These are radios, and smartphones, and tablet computers. And instead of infrared radiation, any other type of electromagnetic radiation can be used, which underlies such well-known wireless communication formats (protocols), such as protocols with the marketing names "Bluetooth" and "Wi-Fi". Switching channels is done either by means of the buttons with numbers located on OK 11, or by means of function buttons, for example, the standard button "Return to the previous channel". This button is installed on almost all consoles currently produced and is designed to switch between the current channel S (S=1, 2, ...) and the previous EA viewed by the user. Moreover, the number of current channels can be several. Return to the previous channel R (R=1, 2, ...) is performed when you are on the current channels for no more than a specified time interval t (t>0). It can be noted that one of the reasons for the user temporarily turning on the current channel S through the console is the appearance of a recurring commercial on channel R. Other special buttons, including those used only in this invention, will be described below.

In FIG. 2 is a view (top view) of the accessories included in the remote control system. In this embodiment, the remote control controls not only the TV 2 but also the radio 13 connected to two speakers 14 and having a compartment 15 for using CDs. The body 16 of the remote control is made in the form of a rectangular parallelepiped, on the upper plane of which OK 11 and rectangular holes 17 are located, designed to improve the penetration of the PZI 5 into the body 16. The KPI 7 itself is created by an emitter (IZL) 18 installed at the top of the body 16. On the side face of the parallelepiped Kn 8, Kn 9, Kn 10 and VD 12 are placed.

In FIG. 3 shows a variant of the remote control circuit 1 using infrared radiation. In this scheme, ISL 18 is connected to a coded signal generation unit (BFS) 19. In almost all remote controls 1, an infrared LED (IR LED) is used as ISL 18. The transmission of coded signals is carried out by its radiation with the appropriate modulation frequency. To recognize the set of commands coming from the remote control 1, various protocols for encoding the transmitted data are used. The first RS5 protocol, which supports 2048 commands, was developed by Philips and is currently used in many TVs. At the heart of BFKS 19, as a rule, a specialized microprocessor (specialized microcircuit) is used, which includes all the elements that provide the formation of coded signals intended to control various electronic devices. The main ones include the control device (CU) 20, the keyboard decoder (DC) 21, as well as the code reader of the pressed button (SKNK) 22, connected through a matching device (SU) 23 to the output stage (VC) 24. Of those not marked on fig. 3 elements can be noted keyboard encoder, internal memory, reset generator, as well as various shift registers. One of the first SAA3010 chips supporting the RS5 protocol was also released by Philips. The microcircuit can address 32 electronic devices in a combined mode - first the electronic device is selected, and then the mode of its operation. The number of the electronic device (address code) is stored in a special register and the command related to this electronic device is transmitted. When pressing the buttons of the keyboard (KL) 25, consisting of OK 11 and special buttons, the corresponding contacts are closed, after which the code of the pressed button (KNK) is read from the output of the SKNK 22, which is fed through the SU 23 to the VK 24, which generates a sequence of pulses that, in turn, they are filled with a periodic signal with a frequency of 36 kHz. Included in the IZL 18 LED (Sv) converts these signals into KPI 7. Each code of the pressed buttons corresponds to predetermined commands that are generated in the electronic device. Thus, the emitted signal is received by the infrared radiation receiver of the electronic device (TV 2 or radio receiver 13) and converts it into electrical impulses, which, after amplification, demodulation and decoding, are converted into an executive command to select a predetermined channel or mode in it, associated with obtaining q -th (q=1, 2, …) user of the audio message. The choice of the type of electronic devices, as well as predetermined modes of their operation, is made on the basis of the code set (KN) stored in the shaper of the channel switching queue (FOPC) 26. It also generates a predetermined sequence of CNCs intended to be fed to the input of the automatic channel switching unit (BAPC) 27 associated with the BFCS 19. This sequence may be included in the SC, and the FPC 26 has a means of inputting (CPB) into it this predetermined CSC sequence. In the following description, different versions of the FPC 26 will be presented. From the BPC 27, the CNC sequence enters the input of the control system 23 only if the output of the comparator unit (BS) 28 of the repetitive sound mute signal (SPS) appears at the output. This SPS is fed to the input of the BAPC 27 via the communication line (LS) 29. Moreover, the BAPC 27 is connected to the comparison unit and is designed to read the code of the pressed button from the FOPC 26 each time a signal appears at the output of the BS 28. Of the other elements that make up the essence of this invention, you can note the elements included in the prototype selected for this invention. This is, first of all, a block for determining the parameters (BOP) 30 of sound radiation and a block for generating a mute signal (BPSOS) 31, which contains, in addition to the BS 28, an electronic key (EC) 32, or a replacement element that performs the function of an electronic key. The parameter determination block 30 calculates the parameters p(i) (i=1, 2, ...) of the sound radiation stream 5 after it is received by the microphone 33 and converted in the analog-to-digital converter (ADC) 34. The parameters are calculated for short fragments (frames), sequentially selected in BOP 30 from the current audio message, and due to the temporary overlap of frames, its accuracy can be increased. Parameters p(i) are, as a rule, well-known sound characteristics (Fourier coefficients, Fourier cosine transform coefficients, spectrum non-uniformity, linear predictive coding coefficients, etc.) and are chosen from the point of view of their invariance to signal distortions and the possibility of quick comparison over them. short fragments for their similarity. The duration of the short fragment is determined in BOP 30 in advance and may be within a few seconds. It can be noted that at present there are quite a few ways to use the p(i) parameters to identify short fragments and compare them with each other. One of them is to create a so-called digital fingerprint (or acoustic digital fingerprint) in the BOP 30, which makes it possible to identify a short fragment solely by its acoustic parameters. An acoustic digital fingerprint is a representation of an audio signal as a set of parameters that describe its physical properties. As an example of the implementation of such a method, we can cite the "MusicID" technology developed by the employees of the "Grace-note" company. Currently, this solution under various names is used in the products of a number of manufacturers of electronic equipment. In particular, a number of models of Sony Ericsson mobile phones have a function of access to the proprietary service "TrackID", which allows you to determine the title of a piece of music by a small fragment of the recording. According to the author, the simplest parameter that characterizes an audio signal in the form of a short audio fragment is its spectrogram, which shows the dependence of the spectral power density of the signal on time. The most common representation of a spectrogram is a two-dimensional plot, with the horizontal axis representing time and the vertical axis representing frequency; the third measurement, indicating the amplitude at a certain frequency, is represented by the intensity or color of each point in the image. At present, the calculation and comparison of spectrograms using the fast Fourier transform is a standard task. Moreover, specialized digital signal processors (DSPs) have been created, the architecture of which is fully optimized for any task related to real-time processing, in particular, an audio signal. On one of these DSPs of the DSPA000 type from Motorola, both BOP 30 and BFSOS 31 can be implemented. The latter, as already noted, consists of EC 32 and BS 28. Moreover, the input of EC 32 and the first input of BS 28 are connected to the output BOP 30 through a bit bus (RS) 35, and the output of the EC 32 and the second input of the BS 28 connected to the memory 36 through the RS 37 and RS 38, operating respectively in the write mode and in the read mode. These modes are controlled via LAN 39 from the control unit 20, which is part of the BFKS 19. The control input of the EC 32 via LAN 40 is connected to the on / off unit (BVO) 41, designed to generate an on or off signal at its output, which ensures the creation and storage of memory 36 parameters of audio fragments excluded from future listening and selected in BPSOS 31 from the current audio message. The memory 36 indicated in the figure can be included in any functional part of the remote control intended for recording, storing and issuing data. It may also be noted that, in order to simplify the scheme, some auxiliary connections are not shown on it. For example, in the process of storing in memory 36 selected in BPSOS 31 parameters of audio fragments, not only LAN 39 can be used, but also other communication lines connecting BFSOS 19 with means of BPSOS 31, BVO 41, FOPC 26 and BAPC 27. It can also be noted that that a detailed description of such elements as microphone 33, ADC 34, EC 32 and BS 28, used to compare the parameters of audio fragments, is presented in the description for patent RU No. 2230375 titled "Speaker recognition method and device for its implementation." The formation of an on or off signal at the output of the BVO 41 is carried out after the corresponding external influence from the user of the TV 2. If the user uses Kn 8 for this, then the BVO 41 is performed in the form of an open contact 42 associated with it, connected to the pressure sensor, made in the form of the first T-flip-flop (hereinafter simply trigger) 43. The latter changes its logical state to the opposite for each active signal at its information input, i.e. each time you press Kn 8 at the control input of EK 32, either a logical zero or a logical unit appears in turn. At the same time, in the initial position at the inverse output of the trigger 43 there is a logical zero, which is transmitted via LAN 40 to the control input of the EC 32. As a result, it is closed and the LED 44 located at the top of the remote control 1 (not shown in Fig. 1) is turned off due to practically zero voltage at the output of the inverter (I) 45. Thus, in the process of recording an unwanted sound fragment into memory 36, Sv 44 is lit, which is a convenient indicator that this mode is on. The formation of an on or off signal can also be carried out after sound or infrared (light) exposure from the user of the electronic device. In the first case, as noted in the description of the patent RU No. 2764675, BVO 41 must be made in the form of a sound radiation receiver, consistent with BPSOS 31, and in the second case, in the form of an infrared or light radiation receiver, also consistent with BPSOS 31. If as BVO 41 uses a sound radiation receiver, then a signal for storing an unnecessary sound fragment to the user can be given by an appropriate voice command, for example, in the form of the spoken word "Pass". To exclude false positives from other sounds, a speech signal recognition unit can be installed in the BVO 41. If a receiver of infrared or light radiation is used as BVO 41, then a signal for storing an unnecessary sound fragment to the user can be given by turning on the second remote control from any electronic device. Recognition of the control signal (CS) from the second remote control, as will be shown below, can be carried out by placing in BVO 41 a simple band-pass filter with a center frequency equal to the modulation frequency transmitted from the second remote control (from any device with a remote control) US. For the convenience of further consideration, let us introduce numerical designations for some not marked in Fig. 3 communication lines. Communication between FOPC 26 and BAPC 27 is carried out through LAN 46, LAN 47 and LAN 48, and the connection of FOPC 26 to SKNK 22 is via LAN 49.

Moreover, one of the inputs of the SU 23 is connected to the BAPC 27 through the LAN 50, i.e. block BAPK 27 is connected with the block of the formation of coded signals.

In FIG. 4 shows one of the options for constructing the BAPC 27. The latter consists of an impulse shaper (FI) 51 connected through its input to the control input of the EC 52, and through its output to the input of a logic element (LE) 53 in the form of an inverter, i.e. input FI 51 is connected via LAN 29 to the output of BS 28. The automatic channel switching unit also includes LE 54 in the form of an "OR" element and a microcontroller (MC) 55 containing a timer 56, non-volatile memory (EP) 57, designed to store the code the pressed "Return to the previous channel" button and the input-output interface (IVV) 58. All these components have different microcontrollers, for example, the PIC16F84A type from Microchip Technology Inc. The start of the timer 56 to count the time T is made from a trigger pulse (ZI) taken from the output of the FI 51 (after the IC arrives at the input of the FI 51) and turns on the timer 56, passing through the LAN 59 and IVV 58. The signal about the end of time (WTS) is removed from the output of the timer after the expiration of time T=To and generates in MK 55 a command to read from EP 57 the said code of the pressed button "Return to the previous channel", which is received via LAN 60 on LE 54. Another pulse created in MK 55 from SOV - a return pulse (IVIS) - comes via LS 47 to one of the inputs of FOPC 26. It can be noted that this pulse is also formed at the moment the EA is turned on (after pressing, for example, the EA on button on the remote control), transferring remote control 1 to its original condition.

As can be seen from FIG. 5 this IVIS goes to the resetting input (OB) of the summing counter (SC) 61, the output of which is fed to two control inputs, one of which belongs to the multiplexer (M) 62, and the other to the demultiplexer (D) 63. Through the latter to LAN 46 and LAN 64 only one of N (N=1, 2,...) data storage elements (ESD) 65 is connected. Each of them can be made either in the form of a register or in the form of a trigger memory. For stable operation, its volume should not exceed the volume of the recorded information package (IP), including, first of all, the CNC, and if there are several EAs, the address code of the EA (device type code). In this case, the repetition of the package will not affect the information already recorded in the ECD 65. Each ECD 65 stores IP, which is pre-recorded using SrV, containing LE 66, 67 in the form of elements "I", LE 68, EC 69 and shaper (F) 70. initial number M (M=0, 1,…). The CNC is recorded in the ECD 65 after pressing Kn 9, after which the contacts 71 associated with it are closed and a logical unit appears at the inverse output of the trigger 72 (in the initial state, the inverse output is zero), which opens the EC 69. This allows the user to write the CNC in EHD 65, selected by D 63 after applying to its control input from SC 61 the initial number M. This recording of the CNC is carried out by means of OK 11, after which the CNC is fed through LS 49, LE 73, LS 74, EC 69 and LS 64 to the input D 63 After the end of the receipt of the CNC at the output of F 70, a counting pulse (SI) occurs, which, passing through LE 67 and LE 68, increases the number of M by one in the SC 61, thereby replacing the n-th (n = 1, 2, .. n) ECD 65 to the (n+1)th data storage element. Thus, after re-selecting the code on OK 11, the code of the selected channel will already be recorded in the (n + 1)-th ECD 65. If necessary, the entry of the address code of the EA type is also performed using the OK 11 buttons before recording the CNC. In another variant, the address code is generated automatically by a special program only on the basis of CNC, each of which corresponds to its own type of EA, which must be pre-enabled when fixing the repeat PZI 5 in the BS 28. Since IP can be repeated, for example, by holding the channel switch button, F 70 should only respond to the first such packet. One of the solutions to this problem is to use a waiting multivibrator as F 70, which is triggered by the leading edge of the input signal and does not respond to its subsequent changes or repetitions until the end of its output pulse. Now let's consider the work of FOPC 26 after its transfer to the operating mode. This mode is started by pressing Kn 9 again, after which a logical unit appears at the direct output of trigger 72, preparing LE 66 for the passage of a counting pulse (SI) through it, increasing the number in MF 61 by one. The initial state of the operating mode of the remote control is characterized by the presence of M 62 of such an IP, which is stored in the ECD 65 after reading from the SC 61 the initial number M and applying it to the control input M 62. When a match pulse (IC) appears at the output of the BS 28, the EC 52 opens and the information packet present in the ECD 65 enters through the M 62, LS 46, EC 52, LE 54 and LS 50 on IZL 18, thereby transferring the user to listening to another channel during the already mentioned period of time To. After its expiration, the timer 56 is triggered and the code of the return button to the previous channel is read from the EP 57, after which the EA switches to the main channel R to its initial state. If during the time To the repetitive sound on channel R has not stopped, then channel S is switched on again in accordance with the established sequence of its switching on. This is explained by the zeroing of the MF 61 by the signal received at its OB via LS 47 after the timer 56 is triggered. The IC that appears also generates a counting pulse at the output of FI 51, which, after passing through In 53, LS 48, LE 66, LE 68, enters the input SC 61, thereby changing ECD 65 with another IP pre-recorded in it, in which there is a code of another channel and which will be turned on when the IP reappears at the output of BS 28. And so on until there is no repetitive sound on the new channel. Here it can be noted that the secondary actions and connections accompanying the operation of the console are not indicated in the figure and in the text. For example, due to the overload of the drawings, the communication line between the CU 20 and the ECD 65 is not marked - it should be used when reading from the ECD 65. It can also be seen that since the M 62 and D 63 are controlled from only one Sch 61, the value of the current number M coincides with number K queue, i.e. M=K.

In FIG. 6 shows a variant of the construction of such a FOPC 26, in which the recording of the CNC or IP can be carried out wirelessly using infrared radiation coming out of the standard remote control. It can be seen from the figure that in this variant, the codes of the pressed buttons are received at the input of the EC 69 by means of an auxiliary infrared receiver (VIR) 75 and an additional microcontroller (DM) 76 connected to it, which performs the work of decoding IR signals. Thus, in the process of recording CNC in ECD 65, not LS 49, but VIP 75 is used, which is very convenient for the manufacturer of standard consoles - no changes are required to be made to them. Indication on the VD 12 recorded in the ECD 65 code is produced in the presence of the inverse output of the trigger 72 logical units.

In FIG. 7 shows a block diagram of FOPC 26, in which a wireless communication module (MBS) 77 is built, for example, of the AVM-200 type, developed by the Korean company Airlogic. Among the recommended applications for this module are all devices using the wireless technology with the marketing name "Bluetooth". The module includes a power amplifier 78, a low noise amplifier 79, and an antenna switch 80 connected through a band pass filter (BPF) 81 to an antenna 82. The low noise amplifier 79 is a controllable two stage amplifier. The power amplifier 78 is three-stage with analog control and, which is very important, with the ability to switch the amplifier to the off state. The command for this operation is generated in the control unit (CU) 83. The design features of the MBS 77 include the presence of an external generator and additional non-volatile memory 84. Both elements are connected to the CU 83, and the module itself is placed in a small-sized shielded case. The output of MBS 77 is connected via LAN 74 to the input of EC 69.

In FIG. 8 shows a block diagram of the FOPC 26, which gives the order of switching on the channels depending on the user name of the electronic device. This is convenient in cases of multiple users with different preferences for the type of audio information. The circuit contains P (P = 2, 3, ...) counters SCH 61 connected to an auxiliary multiplexer (VM) 85, the output of which, in turn, is connected to two control inputs, one of which refers to M 62, and the other - to D 63. The identification data of each user (name, password, etc.) are stored in the user recognition tool (SRP) 86. The latter is connected via a hardware-software interface (API) 87 with an auxiliary microcontroller (VMC) 88 connected via LAN 89 to the control input of the VM 85. The user recognition tool is a software and hardware device that allows you to store user data in secure memory and, if necessary, provide them to the appropriate systems or their components. The hardware-software interface 87 ensures the coordination of the SRP 86 with the VMC 88. Other elements connected to the VMC 88 include a hardware interface (AI) 90, which provides a consistent connection of the MBS 77 to the VMC 88, as well as a trigger 91 connected to open contacts 92. The latter associated with Kn 10 "Enter user code", after pressing which the direct output of the trigger 91 appears a logical zero, allowing the user to enter in the PSA 86 of their identification data. The command for this permission is generated in the VMK 88 and enters the RSH 93, API 87 and RSH 94 in the PSA 86. After entering the identification data, the user selects through the LAN 89 such a SC 61, the output of which is connected via the VM 85, D 63 and M 62 group such ECD 65, in which each user can record only for himself the sequence (order) of turning on the channels with their subsequent reading in the process of listening to the EA. The operation of each group is independent and similar to that described for one MF 61 shown in FIG. 5. Moreover, each group of ECD 65 is "tied" only to "its" initial number M(P), pre-recorded in SC 61 with the number P and which should not intersect with the numbers of other ranges. This can be seen from the fact that each range covers its own switching channels. In other words, the condition for choosing the initial numbers is such a minimum absolute difference between them, which must be greater than (or equal to) the value N, equal to the number of channels recorded in the FOPC 26, i.e. M(P) - M(P±1)>N. Which is obvious, since each number read from R-th SC 61 includes its own channel. Thus, in the initial position, in which IVIS transfers, received via LAN 47, each SCH 61 has its initial number M (P) pre-recorded in it. In this case, the indication of the input mode of identification data, as well as the sequence of switching channels, is carried out by means of Sv 95, which is lit due to the appearance of voltage at the output of the logical element "OR" 96. It can be noted that, since the elements 43.45 noted in the description, 72, 91 can be generated programmatically, their inclusion in this description is made only for the purpose of a more visual description of the operation of Kn 8, 9, 10.

The functional diagrams shown in the drawings of the BAPC 27, FOPC 26, as well as other circuits, are made at the hardware level and can be used as the basis for the development of specialized integrated circuits intended for use only in the remote control 1. As a result, the device becomes not only more reliable but also cheaper. At the same time, the execution of these blocks can be carried out according to other schemes, based, for example, on the use of stack memory.

In FIG. 9 shows a diagram of the interaction of a regular remote control 97 with remote control 1, made according to the scheme shown in FIG. 6. The peculiarity, as already noted, of the regular remote control is the absence of special Kn 8, Kn 9, Kn 10. The described remote control 1 is made as a separate device without OK 11. entering into the remote control 1 the order in which the channels are turned on, or for the purpose of entering user identification data. It is obvious that such a design of remote control 1 simplifies the production of consumer electronics, as it allows manufacturing plants not to change the design of standard remote control 97, designed to interact with manufactured electronic devices. Thus, to automatically turn off the repetitive sound, the user does not need to change the standard remote control 97, but only needs to purchase an additional remote control 1. Two LEDs are installed on its upper side - Sv 44 and Sv 95, as well as IZL 18 and VIP 75.

In FIG. 10 shows a diagram of the interaction of a smartphone 99, for example, of the Apple iPhone 12 type, manufactured by Apple Computers, and the remote control 1, made according to the scheme shown or in FIG. 7 or in FIG. 8. In the first case, the interaction is also performed in order to enter into the remote control 1 the order (sequence) of turning on the channels and the user's identification data. The main difference from the previous version is the use (due to MBS 77) in the data exchange channel (CODE) 100 between the remote control 1 and the smartphone 99 of electromagnetic radiation of the Wi-Fi standard (802.11 b / g specification), as well as an application program called "Remote Control Settings ", reflected on the touch display (SD) 101 in the form of an icon 102. In addition, in the remote control 1 and, accordingly, in the FOPC 26 installed in it, there are no such elements as OK 11, VD 12, Kn 9, Kn 10, as well as elements related with their functioning. The function of the latter is performed by the application program "Remote control settings" and the software coordinated with it installed in BU 83 or in VMK 88. The function of the main keyboard is performed by the standard remote control 97. The body of the remote control 103 is an elongated parallelepiped. IZL 18, VIP 75, Sv 44 and Sv 95 are located on its top panel. Antenna 82 is located inside the housing 103. If the remote control is made according to the scheme of Fig. 7, then VIP 75 and Sv 95 will be absent. A distinctive feature of modern smartphones is their operating system, which is open for software development by third-party developers. Its installation allows the smartphone 99 to be used as a universal means of recording in the remote control 1 both the channel order and the user's identification data. The application program "Remote control settings" is invoked by touching (calling a touch event) the icon 102 with a finger or a stylus. As a result, a window appears, through which the user's name or code is entered, as well as other information.

In FIG. 11 shows the graphical interface that appears on the LED 101 after confirming the entered username, such as the name "David", or his code. For each name or code located in field 104, the graphical interface contains field 105 for recording the channel, including on different electronic devices, as well as field 106 (located to the right of field 105) for recording the K number (K = 1, 2 ,...) of the queue (or sequence) of switching on the selected channel S(K), where S is the designation of the channel. During the marked recording process, each channel can be assigned either a channel number or a word designation, such as "Home". If the number of channels is large enough, a scroll bar 107 appears on the right border. The scroll bar consists of the following parts. Along the edges are graphic buttons (GK) 108, 109 with the image of arrows, which serve to slightly move the fields 105, 106. If you click on such a button, the fields will move in the direction indicated by the arrow. Between the arrows is a key 110, which may be larger or smaller. The height of the key 110 can be used to estimate the number of fields 105, 106. The location of the key 110 along the length of the scroll bar 107 indicates the relative position of the fields 105, 106 within the workspace 111 associated with the application program.

In FIG. 12 shows a variant in which the electronic device controlled by the remote control is made in the form of a TV 2, and the remote control is in the form of the structure shown in FIG. 10, but without button 8. In this version, the remote control 1 is controlled by an auxiliary control panel (VPU) 112, which has only one button 113. The latter performs the function Kn 8 "Isolation of a sound fragment" and is intended for transmission by means of an auxiliary radiation flux (VPI) 114, received by the auxiliary receiver (AP) 115, the command to open the EC 32. The formation of the ARI 114 is carried out by the auxiliary emitter (AI) 116 installed on the front wall of the housing 117. The advantage of this solution is a significant simplification of the design of the remote control 1, which can be made in the form of an additional device to one or more regular remote control 97. In view of the absence of the need for digital coding of the VPI 114, the implementation of the VPU 112 can be done according to a very simple scheme.

In FIG. 13 shows a variant of such a scheme. It contains only a pulse generator (PG)118, which generates a sequence of pulses with a frequency f=1 MHz. These pulses are fed to the frequency divider (DF) 119 and are converted into a sequence of pulses with a frequency of F=10 kHz, which, in turn, are fed to the input of the power amplifier (PA) 120, which supplies the VI 116. The inclusion of the VPU 112 is performed by simply closing the open contact 121 associated with Kn 113. After that, voltage from the battery 122 is applied to the GI 118, DC 119 and PA 120 and the VI 116 begins to emit a modulated VPI 114.

In FIG. 14 shows a diagram of the on / off block (BVO) 41 designed to work with the VPU 112. In addition to the elements 43, 45, 44 already used in the BVO 41, this block includes the VP 115 in the form of a photodiode that receives the VPI 114, and connected between is an input amplifier (VU) 123, PF 124 with a center frequency F = 10 kHz, an amplitude detector (AD) 125 with an integrator, a comparator (K) 126 and a pulse shaper (FIn) 127. The operation of each of these elements is standard and is described in technical literature. In our case, it is associated with the receipt (after pressing Kn 113) at the output of FIN 127 such an active signal that affects the information input of the T-flip-flop 43 as well as after pressing the button 8 "Isolation of the audio fragment tape". In other words, after pressing Kn 113, a pulse occurs at the output of FIN 127, which changes the logical zero to a logical one at the inverse output of the T-flip-flop 43, which, in turn, is transmitted via LAN 40 to the control input of EC 32.

The operation of the remote control 1 is carried out in accordance with the schemes of the algorithms presented in Fig. 15 and FIG. 16. Their practical implementation is carried out by means of special and standard software, under which the remote control 1 operates, as well as the EA controlled by it. Standard software can be stored in the internal memory of such elements as BFKS 19, FOPC 26, BAPC 27, MBS 77 and must include an exchange protocol between the remote control 1 and the EA, i.e. include a set of formalized rules, procedures and specifications that determine the format and method of data exchange between RC 1 and EA. In addition, this set should also include a data exchange protocol within the remote control 1 itself. When using additional tools in the form of a smartphone 99 or standard remote control 97, part of the software must be stored in their internal memory. The execution of step 128 to create a channel inclusion sequence depends on the need for such a procedure. If it is necessary ("Yes" in condition 129), then the execution of the algorithm includes actions such as 130, 131 and 132. The execution of the action 130 to set the user code or name is achieved through Kn 10 "Enter user code". After pressing it on VD 12 or SD 101, a field appears for entering the name of the q-th user, which is done using either the OK numeric buttons 11 or the graphic buttons that appear on SD 101. After completing the input of each code, the input end button is pressed, for example, under the generally accepted designation "OK" (action 131). As a result, a field appears on the corresponding display, in which, for the name already entered, the channel switching sequence is entered, for example, this is 07141125 (step 132). Located in the CU 20 decoder decrypts the contents of this input. As a result, each time the SPS appears at the output of the BS 28 for a given user, the following channels are switched on: 07 (1), 14 (2), 11 (3), 25 (4). In parentheses after the channel number, the number of the turn on of the EA is indicated. If, after step 132, a new user is expected to enter ("Yes" in condition 133), then for the (q+1)th user (step 134), steps 130, 131, 132 are repeated. Otherwise, action 135 is performed to store in memory 36 for each q-ro user of the order (sequence) of switching on channels.

In FIG. 16 shows the algorithm for the interaction of the remote control and EA. After performing step 136 to turn on electronic devices, as well as step 137 to receive microphone 33 on the main channel R of sound radiation 5, converting its analog output signal to ADC 34 and forming parameters in BOP 30, they are transmitted via RSH 35 to the input of EC 32 and the first input of the BS 28. If the memory 36 parameters p(i) are not recorded ("No" in condition 138), then the action 137 continues. In this case, all further user operations to control the TV 2 and the radio 13 are carried out using the OK buttons 11 If the user decides to exclude the current sound fragment from future listening, then the recording of its parameters p(i) in memory 36 is carried out by pressing button 8 or button 113 twice. - ends. After that, the parameters of the unwanted sound fragment appear in the memory 36. If the sound fragment in the form of, for example, an advertising insert, has a short duration (of the order of 5 ... 10 s), then the division in the BOP 30 of this fragment into shorter sound fragments is not performed. If in the memory 36 the parameters of the fragments have already been recorded ("Yes" in condition 138), then action 139 is performed to compare them in the BS 28 with the parameters of the current fragments coming via RSH 35 from the BOP 30. If the parameters match with a given degree of accuracy ( "Yes" in condition 140) at least two sound fragments (current and stored in memory 36) in BPSOS 31 generate a coincidence pulse that enters the BAPC 27 via LAN 29 and opens EC 52. As a result, from the ECD prepared in accordance with the established sequence 65, the CNC is extracted, which arrives first via LAN 46 at the input of EC 52, and then via LAN 50 at the input of VK 24. As a result, by means of KPI 7 and in accordance with the order established in FOPC 26, a pre-selected channel S (K) is switched on on the corresponding EA (action 141). If there are several EAs, then the required EA is first switched on, and then the channel S(K) used and recorded in the FOPC 26 is switched on. Simultaneously with the opening of the EC 52, a signal appears at the output of the FI 51, which is fed through the LAN 48 to the input of the SC 61, increasing the number M stored in it by one and thereby preparing the new ECD 65 for reading from it the CNC related to the new channel S(K ). In addition, this signal starts the timer 56, which, by means of the MC 55, after the expiration of the time To ("Yes" in condition 142), generates a command to read from the EP 57 the code of the pressed "Return to the previous channel" button. In our case, this command reflects action 143 on the return of EA to the main channel R. Simultaneously with this command, another pulse generated in MK 55 enters via LAN 47 to the OB of the summing MF 61 and transfers it to its original position. Thus, if the unwanted sound continues to be found on the R channel due to the reset of MF 61, action 141 will be duplicated. If, after performing action 141, an unwanted repetitive sound also appeared on channel S(K), but before the time To ("No" in condition 142) expired, then after condition 140 is met, there will be an automatic transition to the next channel S(K) in accordance with set number Go to queue. It can be noted here that when choosing the values "To" and "t" (t is the above-mentioned time period associated with the initial setting of the EA's return button to the previous channel), the following condition must be met: t>To. It can be seen that if this condition is violated, the transition to the main channel after the expiration of the interval To may not take place.

Let us now give a specific example illustrating the operation of the system shown in FIG. 1 of the remote control (as well as those presented in the description of the main circuits), in the process of its interaction with the EA in the form of a TV 2. Moreover, the circuit parameters of the device mentioned in the text are as follows: To=30 sec, N=3, M=1. The TV has several channels, three of which are sports and are included in the user's list as the most watchable. However, the peculiarity of these channels is a large temporary amount of advertising inserts, the parameters of which the user, through Kn 8, recorded in advance in memory 36. Before turning on the TV 2, the user, using the SrV included in the FOPC 26, wrote down the button codes for these channels in accordance with the desired turn on. The recording was carried out after pressing Kn 9, as a result of which a logical unit appeared at the inverse output of trigger 72, which opened EC 69. This enabled the user to write code 391 (CNC \u003d 391) of channel S (l) in ECD 65, selected by means of D 63 initial number M = 1 from SC 61. This recording was carried out by pressing the OK 11 channel buttons S (l) and transmitting code 391 read from the output of SKNK 22 via LAN 49 and LAN 64 to the input of ECD 65. After entering code 391 (process input was reflected in VD 12) on OK 11, the input end button was pressed, after which, from the preparation pulse (IMP) formed for this reason at the output of LE 73, SI was obtained from the output of F 70, which, after passing through LE 67 and LE 68, increased in MF 61 the number M to two (M=2), thereby transferring the code entry 128 of the channel button S(2) to the second ECD 65.

Button code 134 was recorded similarly for the third channel S(3). Since the value of the current number M coincides with the number K of the queue, then in the process of recording all three channels, their switching order was set automatically, which will also be seen from the further description. After recording all three channels, Kn 9 was pressed again, as a result of which LE 66 became open for the passage of SI through LS 48, and LE 67 became closed for the passage of these pulses.

Let the user use channel S(2) as the main channel R in order to watch a football match on it. Moreover, after turning on the TV using the remote control 1, Sch 61 was transferred to its original state by applying M = 1 to the control inputs M 62 and D 63. After the appearance of an advertisement for the drug during the match, an IS appeared at the output of BFSOS 31, which arrived via LS 29 to BAPK 27 and opened the EC 52. As a result, the code 391 was read from the ECD 65, which, after entering the LAN 50 at the input of the VC 24, caused the channel S(l) to turn on. At the same time, the IC caused a counting pulse at the output of FI 51, which came from LE 53 to the input of SC 61, increasing the number M to two (M = 2), and thereby preparing the next ECD 65 in turn with the code 128 of channel S (2 ). Since vitamin advertising was also present on channel S(l), IS appeared again at the output of BPSOS 31, as a result of which code 128 was read from another ECD 65 and the main channel S(2) was turned on, through which the drug advertisement had not yet ended and on IS appeared again at the output of BS 28. With its arrival at the output of FI 51, an SI appeared, which, having passed LE 53 and LS 48, increased the number M to three (M = 3), thereby connecting to LS 46 the next in turn ECD 65 with the written in it code 134 of channel S(3), which was broadcasting another football match and which was immediately turned on after the discovery of an unfinished drug advertisement on channel S(2). Simultaneously with the switching on of the S(3) channel, the trigger pulse in the MK 55 turned on the timer 56, which, after 30 s had elapsed (during this time, there was no undesirable sound), issued an SOW and, after reading the code of the "Return to the previous channel" button from the EP 57, was turned on again the main channel S(2) with the football match being viewed by the user.

The advantage of this invention is to improve the performance of consoles, the design of which already has built-in microphones that provide sound reception from electronic devices controlled by these consoles. A particularly great effect from the use of this invention can be obtained from those remote controls for electronic devices that are used in the mode of frequent muting by users of their sound coming from repetitive commercials or repetitive audio information that is undesirable for them. This is explained by a decrease in the loss of sound information due to the exclusion of long pauses that occur when the sound is turned off.

In conclusion, it can be noted that the considered examples are given only to illustrate the possibility of carrying out the invention. They do not limit the scope of legal protection provided in the claims. At the same time, a person skilled in the art, on the basis of the presented description, can easily propose other embodiments of the invention that expand its functionality. Also, without much difficulty, new features introduced into these variants can be proposed. We give only some examples of such options and features, but much more can be offered. This is a remote control that provides a temporary automatic decrease in the sound level on the electronic device immediately after it is transferred to the main channel, which increases the comfort of the perception of the sound that the user does not need, if it is preserved after this transfer. This is a remote control that provides a temporary automatic decrease in the sound level on an electronic device during a temporary transition from the main to the current channel, which also increases the comfort of the user's perception of unnecessary sound. This is an option in which only the sound level is reduced in the EA by means of the remote control, and not completely turned off when repeated sound information appears. This is an option to use such artificial intelligence tools in the remote control, after training which the selection and memorization of channels preferred by the user occurs automatically.

Claims (7)

1. Remote control containing a microphone, a memory and a unit for generating coded signals, including codes of pressed buttons stored in memory and providing remote switching of channels on an electronic device emitting a sound stream, as well as a unit for determining the parameters of sound radiation connected to the microphone and associated with it a mute signal generation unit, containing a unit for comparing the current sound parameters with the parameters of sound fragments allocated and stored in memory by means of an on/off unit, characterized in that it contains an automatic channel switching unit and an associated channel switching queue generator, moreover, the automatic switching unit channels is connected to the comparison unit and is designed to read the code of the pressed button from the channel switching sequencer at each appearance of a signal at the output of the comparison unit, and the channel switching sequencer is intended is designed to establish a predetermined sequence of occurrence of codes of pressed buttons at each occurrence of a reading signal from the automatic channel switching unit, while the automatic channel switching unit is connected to the coded signal generating unit, and the channel switching queue generator has means for inputting a predetermined sequence of pressed button codes into it . 2. The remote control according to claim 1, characterized in that the means for entering a predetermined sequence of codes of the pressed buttons contains a button for enabling the mode of the above input, associated with the control input of the electronic key, connected through its output to the data storage elements, and the input - to being in the composition block for generating coded signals to the reader of the code of the pressed button, wherein each data storage element contains the code of the pressed button, issued in accordance with the established sequence to the input of the automatic channel switching unit. 3. The remote control according to claim 1, characterized in that the means for entering a predetermined sequence of codes of pressed buttons contains an infrared receiver and is made in the form of a button for enabling the above input mode, connected to the control input of the electronic key connected through its output to the data storage elements, and input - to an auxiliary infrared receiver, coordinated with a regular remote control designed to control an electronic device, while each data storage element contains a code of the pressed button, issued in accordance with the established sequence to the input of the automatic channel switching unit. 4. The remote control according to claim 1, characterized in that the means for entering a predetermined sequence of codes of pressed buttons contains a wireless communication module and is made in the form of a button for enabling the mode of the above input associated with the control input of an electronic key connected through its output to the data storage elements, and the input - to the wireless communication module, coordinated with a computer or smartphone, in the internal memory of which the codes of the pressed buttons are stored. 5. The remote control according to claim 1, characterized in that the automatic channel switching unit contains a timer associated with the memory for storing the code of the pressed channel return button and designed to count down the time until the electronic device is reset. 6. Remote according to one of paragraphs. 1-5, characterized in that the on/off unit contains an infrared radiation receiver, coordinated with the mute signal generating unit, as well as with an auxiliary control panel having at least a button for selecting sound parameters intended for their recording in memory. 7. Remote according to one of paragraphs. 1-5, characterized in that the channel switch queue generator comprises a user identification means associated with a storage node of a certain number of independent channel switch queues, each of which is intended for use by a respective user.

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