RU2764675C1 - Remote control unit - Google Patents

Abstract

FIELD: electronics.

SUBSTANCE: invention relates to the field of electronics, namely to the means of remote control of household electronic devices. The expected result is achieved due to the remote control unit, which contains a microphone, memory and an associated unit for generating coded signals that provide remote control of the level of sound radiation coming out of the electronic device controlled by the remote control unit, while the remote control unit additionally contains a unit for determining the parameters of sound radiation and an associated unit for generating a mute signal, providing automatic generation of a signal of a change in the level of sound radiation after it is isolated by means of a block of enabling/disabling predefined parameters of sound radiation and comparing them with the parameters of sound radiation present at the output of the parameter detection unit, while the unit for generating a mute signal contains a comparison unit and an electronic key connecting a unit for parameter determination and memory.

EFFECT: expanding the functionality of the remote control, which consists in providing automatic shutdown of repetitive sound on a controlled electronic device.

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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, music centers) intended for use at home have special remote controls that allow you to control the most important functions of these devices from a distance. One of them - mute - is mainly used to prevent listening to repetitive advertising.

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 previously transmitted audio content.

This analog is a prototype of the claimed invention and is a remote control containing a microphone, a memory and an associated block for generating coded signals that provide remote control of the level of sound radiation coming out of an electronic device controlled by the remote control.

The disadvantage of this, as well as other known remotes, 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.

The problem to which the invention is directed is the creation of a remote control with automatic shutdown of repetitive sound.

The problem is solved due to the fact that the remote control containing a microphone, a memory and an associated block for generating coded signals that provide remote control of the level of sound radiation coming out of an electronic device controlled by the remote control, additionally contains a block for determining the parameters of sound radiation and associated with it a mute signal generation unit that automatically generates a signal for changing the level of sound radiation after selecting in it, by means of a block on / off, predetermined parameters of sound radiation and comparing them with the parameters of sound radiation present at the output of the parameter determination unit, while the microphone is connected to the input of the unit parameters determination, and the mute signal generation unit - with memory, on/off unit and with coded signal generation unit.

The technical result of the invention is to expand the functionality of the remote control, which consists in automatically turning off the repetitive sound on the controlled electronic device. 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 controlled by it;

fig. 2 shows a first version of the remote control circuit;

fig. 3 shows a second version of the remote control circuit;

fig. 4 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 FIG. 1 shows the main means included in the system using remote control elements. Controlled by a remote control (RC) 1, the electronic device is made in the form of a TV 2, which has an infrared radiation receiver 3 and an electro-acoustic transducer 4. The latter creates sound radiation 5, which is received by the remote control 1 using a microphone located outside or inside the housing 6. The latter also has a special compartment for installing a battery, usually consisting of two batteries. The encoded stream 7 of infrared radiation (IR radiation) is created 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 "Automatic mute" button 8, the LED 9 for enabling the "Automatic mute" mode and the main keyboard (OK) 10, consisting of function buttons responsible for various TV settings 2. To general settings relating to all electronic devices with electroacoustic transducer 4, you can include turning off the sound, for example, during repetitive advertising. These include radios, 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".

In FIG. 2 shows the first version of the scheme of the remote control 1 using infrared radiation. In this scheme, the number 11 denotes the emitter (IL) of infrared radiation connected to the coded signal generation unit (BFS) 12 associated with the memory 13 or having this memory in its composition. This fact in Fig. 2 is marked as a rectangle outlined by a dotted line. In almost all remote control 1, an infrared LED (IR LED) is used as an emitter 11. The transmission of coded signals is carried out by its radiation with the appropriate modulation frequency. Connected to the BFKS 12 open contacts 14 and 15 are connected to the buttons of the main keyboard 10. In this case, open contacts 15 are connected to the standard mute button. Each time the contacts 15 are closed, either the sound emission 5 (sound) is turned off or it is turned on (if the sound was turned off). 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 the BFKS 12, as a rule, a specialized microprocessor (specialized microcircuit) is used, which has in its composition all the elements that ensure the formation of coded signals intended to control the TV 2. The main ones include a control device, a keyboard decoder, shift registers, memory . One of the first SAA3010 chips supporting the RS5 protocol was also released by Philips. When the remote control buttons are pressed, the corresponding contacts 14, 15 are closed, after which the transmitter chip is activated and generates a sequence of pulses that are filled with a periodic signal with a frequency of 36 kHz. Included in the ISL 11 LED converts these signals into infrared radiation. The emitted signal is received by the infrared receiver 3 and converted into electrical impulses, which, after amplification, demodulation and decoding, are converted into the corresponding executive command. Thus, when the contacts 15 are closed, the flow 5 of sound radiation stops. Of the additional elements that make up the essence of this invention, it is possible to note the block for determining the parameters (BOP) 16 of sound radiation and the block for generating the mute signal (BPSOS) 17. The block 16 for determining the parameters calculates the parameters p(i) (i=1, 2, ...) sound radiation 5 after it is received by microphone 18 and converted in an analog-to-digital converter (ADC) 19. The parameters are calculated for short fragments (frames) sequentially allocated in BOP 16 from the current audio message, and due to the temporary overlap of frames, it can be increased work accuracy. Parameters p(i) are, as a rule, well-known characteristics of sound (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 ability to quickly compare them short fragments for their similarity. The duration t (t>0) of the short fragment is determined in advance in BOP 16 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 BOP 16, 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 DSP56000 type from the Motorola company, BOP 16 and BPSOS 17 can be implemented. The latter consists of a controlled key (K) 20 and a comparison unit (BS) 21. Moreover, the input of the key 20 and the first input of BS 21 are connected to the output of the BOP 16 by means of a bit bus (RS) 22, and the output of the key 20 and the second input of the BS 21 are connected through the RS 23 and RS 24 to the memory outputs 13, operating respectively in the write mode and in the read mode. These modes are controlled via the communication line (LAN) 25 from the control unit included in the BFKS 12. The control input of the key 20 via LAN 26 is connected to the on / off unit (BVO) 27, designed to generate an on or off signal at its output, providing creating and storing in memory 13 parameters of audio fragments excluded from future listening and selected in BOP 16 from the current audio message. The connection between the BFKS 12 and the BPSOS 17 is carried out by means of the key 33. It may be noted that, in order to simplify the diagram, some auxiliary connections are not shown on it. For example, in the process of storing in memory 13 the parameters of audio fragments selected in the BOP 16, not only the LAN 25, but also other communication lines connecting the BFKS 12 with the output of the BVO 27 can be used. It can also be noted that a detailed description of such elements as microphone 18, ADC 19, K 20, BS 21, used to compare the parameters of audio fragments, is presented in the description of the patent RU No. 2230375 under the title "Speaker recognition method and device for its implementation". The formation of an on or off signal at the output of the BVO 27 is carried out after the corresponding external influence from the user of the TV 2. If the user uses button 8 for this, then the BVO 27 is performed in the form of an open contact 28 associated with it, connected to a pressure sensor made in the form of T -trigger 29.

The latter changes its logical state to the opposite for each active signal at the information input, i.e. each time you press the button 8 on the control input of the key 20 alternately appears either a logical zero or a logical unit. At the same time, in the initial position, at the inverse output of the T-trigger 29, there is a logical zero, which is transmitted via LAN 26 to the control input of the key 20. As a result, the key 20 is closed, and the LED 9 is turned off due to almost zero voltage at the output of the inverter 30 Thus, in the process of writing an unwanted sound fragment to memory 13, LED 9 lights up, which is a convenient indicator of the activation of this mode. 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, BVO 27 must be made in the form of a sound radiation receiver, consistent with BFSOS 17, and in the second case, in the form of an infrared or light radiation receiver, also consistent with BFSOS 17. If a sound radiation receiver is used as BVO 27, then the signal for memorization 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 in BVO 27, a speech signal recognition unit can be installed. If a receiver of infrared or light radiation is used as BVO 27, 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 signal from the second remote control can be carried out by placing in BVO 27 a simple bandpass filter with a center frequency equal to the modulation frequency transmitted from the second remote control (from any device with a remote control) pulses. The output of the BS 21 is connected via LAN 31 to the input of the timer 32 and to the control input of the key 33, and the control input of the key 34 is connected to the output of the timer 32. The latter is designed to count the time after the automatic turning off of the sound radiation from the electronic device in order to transfer it to its initial state. After the expiration of the time t* (t*>0) pre-set in the timer 32, a pulse appears at its output, which closes the contacts 15 by means of the key 34 and thereby transfers the TV 2 to its initial state associated with the restoration of sound radiation 5. Choosing the value of time t* is made from the average time of appearance of unwanted sound radiation 5. In the case of advertising, this is the average time of its sound after it appears on the TV screen 2. If an unwanted sound appears before the time t*, it will immediately turn off due to the re-formation of the mute signal in the BFSOS 17.

In FIG. 3 shows a diagram of the remote control 1, in which the artificial intelligence tool (AI) 35, connected to the BFKS 12 through the LAN 36 and the control input of the key 37, performs the functions not only of determining the time t*, but also of improving the accuracy of the BPSOS 17. With the aim of To simplify the circuit, the BVO 27 is not shown in the figure. To implement the last task, the SII 35 must also be connected to the output of the BOP 16. In this case, the SII 35 provides the creation in the BFKS 12 of a command to change the level of sound radiation (or turn it off) coming out of the controlled by the remote control electronic apparatus. The artificial intelligence means 35 is for using artificial intelligence (AI) technology when deciding whether to mute or change the volume. The latter is ensured by connecting to the corresponding button 14 of an additional controlled key. By means of the button 14, the volume of the sound is adjusted by forming a rectangular pulse in the SII 35, which opens an additional key for a certain time in it. In the general case, the structure of the AI used for the two-alternative choice of the correct decision (in our case, the decision to turn off the sound) includes four main blocks - a database (DB) 38, a neural network (NN) 39, a single-threshold decision device (RU) 40 and an intelligent interface (InI) 41, allowing the user to enter new information into the database 38 after the next mute. In some embodiments, DB 38 can be stored in memory 13. Voltage U (U>0) is removed from the output of NS 39, which is compared with the threshold level of RU 40. The latter has a threshold level U* (U*>0) and when U>U * generates a signal S(t), for example, in the form of a rectangular pulse that opens the key 37 and thereby turns off the sound of the TV 2. The implementation of the SII 35 may have different options. In one of them, the SII 35 can be represented as a separate processor for neural network calculations, and in the other, it can continuously send data to the "cloud" with the neural network in it. As an example of a separate module, you can bring the Kirin 980 processor from Huawei, which is specially designed to work with machine learning. Learning algorithms for a neural network come with and without a "teacher". With the "teacher", which is the user of the TV 2, the neural network 39 is provided with a certain selection of training examples, for example, in the form of mute already committed (automatically) positively evaluated by the "teacher". The input of the assessment is made last by means of an input device (for example, by means of preselected buttons of the main keyboard 10) connected to the SII 35. The criterion for "correct answer" is the assessment of the user by the electronic device. On its basis, after the above comparison, the weight coefficients of the input data received after the sound is turned off are calculated. In the process of work, the input data received via RSh 22 in the form of sets of parameters p(i), multiplied in SII 35 by their weight coefficients, are fed to the input of NS 39, where, after summation, they are compared in RU 40 with the sums of the corresponding sets of known data read from the database 38 and received a positive assessment from the user of TV 2. If the threshold level U* of even one "correct" set is exceeded, the mute signal from TV 2 is removed from the output of RU 40. When using AI to select a decision to turn on the sound (after it is automatically turned off), the SII 35 must be connected with BFKS 12, the output of BOP 16, as well as with BPSOS 17 and the sound button included in the main keyboard 10. In this case, the input data must be presented as j (j=1, 2, ...) sets of parameters pj(i) and their associated time intervals T(j) multiplied by their weights. The time intervals T(j) between the automatic turning off of the sound and its inclusion are determined in the SII 35 after the activation signal arrives at it either via the LAN 31 or from the main keyboard 10. When the sound is automatically turned on (positively assessed by the user), the weight coefficients will increase, and when manual - descend. It can be seen that during the operation of the TV 2 due to the training of the NS 39 by the "teacher" (the user of the TV 2), the accuracy of determining the time of automatic sound activation will increase. It may be noted here that, shown in Fig. 2 and FIG. 3 circuits BOP 16, BFSOS 17, ADC 19 and BVO 27 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 remote control 1. As a result, it becomes not only more reliable, but also cheaper. But, if the operation algorithms of these blocks are implemented by software, then the special program (SP) used for this must be stored in memory 13. If a smartphone or tablet computer is used as a remote control, then a special program must be placed in their internal memory.

In FIG. Figure 4 shows the operation algorithm of the remote control 1. The practical implementation of this algorithm is carried out using standard and special software stored in memory 13 or in the memory of a smartphone used as a remote control. After performing step 42 for transmitting sound radiation 5 from TV 2, as well as step 43 for receiving it by microphone 18, converting it to ADC 19 and forming parameters in BOP 16, they are transmitted via RSH 22 to the input of key 20 and the first input of BS 21. If the parameters p(i) are not recorded in memory 13 ("No" in condition 44), then action 43 continues. In this case, all further user operations to control TV 2 are carried out using the buttons of the main keyboard 10. If the user decides to exclude from future listening the current sound fragment, then the recording of its parameters p(i) into memory 13 is carried out by pressing button 8 twice. In this case, after the first press, the key 20 opens and the recording begins, and after the second press, it ends. After that, the parameters of the unwanted sound fragment appear in the memory. If a 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 BOP 16 of this fragment into shorter sound fragments is not performed. If in memory 13 the parameters of the fragments are recorded ("Yes" in condition 44), then action 45 is performed to compare them in BS 21 with the parameters of the current fragments coming via RSH 22 from BOP 16. If the parameters match with a given degree of accuracy ("Yes "in condition 46) at least two sound fragments (current and stored in memory) in BPSOS 17 generate a signal that enters the control input of key 33. As a result, it opens, closes contacts 15 and in BFKS 12 a signal is generated that turns off the sound from electronic device (step 47). It can be noted that the comparison process (action 45) occurs after the synchronous arrival of the SL 25 to the control input of the memory 13 of the read pulse, and to the control input of the BS 21 - enabling pulse.

The advantage of this invention is to improve the performance of those remote controls for electronic devices that are designed to control or mute the sound that accompanies the information they transmit. Especially great effect from the application of this invention can be obtained from those remote controls that are used in the mode of frequent mute coming from repetitive commercials or unwanted repetitive sound.

Claims (7)

1. A remote control containing a microphone, a memory and an associated block for generating coded signals that provide remote control of the level of sound radiation coming out of an electronic device controlled by the remote control, characterized in that it contains a block for determining the parameters of sound radiation and an associated signal forming block mute, which provides automatic generation of a signal of a change in the level of sound radiation after selection in it by means of an on / off block of predetermined parameters of sound radiation and their comparison with the parameters of sound radiation present at the output of the parameter determination unit, while the microphone is connected to the input of the parameter determination unit, and a mute signal generation unit with a memory, an on/off unit and a coded signal generation unit, while the mute signal generation unit comprises a comparison unit and a connecting unit for determining parameters and memory electronic key, the first input of the comparison unit is connected to the output of the parameter determination unit, and the second - to the memory, while the output of the comparison unit is connected to the coded signal generation unit, and the control input of the electronic key is connected to the on/off unit. 2. The remote control according to claim 1, characterized in that it is made in the form of a smartphone or tablet computer. 3. The remote control according to claim 1, characterized in that the on / off unit is made in the form of a sound radiation receiver, coordinated with the mute signal generation unit. 4. The remote control according to claim 1, characterized in that the on / off unit is made in the form of one or more buttons connected to a pressure sensor, coordinated with the mute signal generation unit. 5. The remote control according to claim 1, characterized in that it contains a timer connected to the block for generating the mute signal and the block for generating coded signals, designed to count the time after the automatic switching off of sound radiation from the electronic device in order to transfer it to its original state. 6. The remote control according to claim 1, characterized in that the block for generating the mute signal is part of the block for generating coded signals. 7. The remote control according to claim 1, characterized in that the on / off unit is made in the form of an infrared or light radiation receiver, coordinated with the mute signal generation unit.

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