KR102657293B1 - Control devices for controlling electronic products - Google Patents

Abstract

The present invention relates to a control device that controls electronic products, and more specifically, to a method of preventing unnecessary power consumption in a control device that controls electronic products.
To this end, the control device of the present invention includes a first noise filter that filters signals in a frequency band other than the set frequency band among signals received from a microphone; an amplifier that amplifies the signal received from the first noise filter; a second noise filter that filters signals in a frequency band other than the set frequency band among the signals amplified by the amplifier; a comparator that generates a trigger signal when the frequency band of the signal received from the second noise filter is a frequency band between low level and high level; When a trigger signal is received from the comparison unit, it includes a microcomputer that supplies power to the voice recognition module using a load switch.

Description

{Control devices for controlling electronic products}

The present invention relates to a control device that controls electronic products, and more specifically, to a method of preventing unnecessary power consumption in a control device that controls electronic products.

These days, there are a lot of advertisements for home IoT (Internet of Things), especially smart home control, led by telecommunication companies.

Recent home network system technology uses a network inside and outside the home to connect the lighting, heating, cooling, crime prevention, and communication functions of the home into one system, enabling remote access and control, and providing a two-way communication service that allows the use of various contents. It refers to a system that has all the functions that provide an environment. With the active spread of various wired and wireless communication technologies such as power line communication and wireless communication, interest in and demand for network-based home automation has increased. In particular, with the spread of information devices such as smartphones and personal mobile devices, these are being used as terminals for home networks. It became possible.

In addition, recently, along with the rapid development of digital signal processing algorithms and hardware, the development of voice communication systems has been actively conducted. In particular, as the means of communication between humans and systems is being replaced by the user's voice from the keyboard or mouse, research aims to control devices and provide information services by applying voice recognition technology to wireless home network systems beyond the scope of simple voice recognition. is in progress.

In addition, it is necessary to increase the speech recognition rate for speakers in variable positions considering the user's mobility. Therefore, variable position high-voice recognition technology is required to build a high-performance home network system.

According to the prior art described in Korean Patent Publication No. 2013-0027920, remote control of electrical and electronic products connected to a wired/wireless network through a telephone or other voice-using information device outside the home is used for remote voice recognition control. A home automation and home network system status monitoring and control device that uses remote voice recognition to control the status of a specific device or the status and situation of all devices by voice, and is controlled using a power line. There has been research on. And recently, the fields to which voice recognition technology is applied are increasing widely.

Voice recognition technology in these fields is commercialized beyond the scope of research activities, and commercialized voice recognition technology shows good performance in environments such as the research stage, but performance is deteriorating in actual recognition environments. Voice signals collected under general indoor environmental conditions are usually degraded by reverberation and additional noise. In fact, signals received by a microphone system in a closed space such as a home or an auditorium, video conference room, or classroom are affected by direct transmission waves and walls. Reflected waves are added. Ultimately, since it is difficult to clearly obtain the actual sound generated, it is necessary to apply sound quality improvement techniques.

In addition, voice recognition devices that currently recognize voices and are controlled by home appliances are always supplied with power. In other words, the voice recognition device recognizes voices in real time using the constant power supplied, and controls home appliances according to the recognized voices.

However, when controlling household appliances in the house using a voice recognition device that cannot be supplied with power at all times, a problem arises in that the battery must be replaced frequently due to the capacity of the built-in battery. In other words, since it is impossible to know when the user will control the home appliance using his or her voice, the voice recognition device must supply power to the microphone and voice recognition module in real time, which leads to the problem of having to frequently replace the built-in battery.

Therefore, when it is necessary to control home appliances using a voice recognition device that cannot be supplied with power at all times, a method of supplying power to the module constituting the voice recognition device is required.

Korea Public Utility Model No. 20-2013-0000822 (Design name: Standby power blocking device for remote control system) Korean Patent Publication No. 2013-0105219 (Title of invention: Electronic device for controlling power using voice recognition and method for controlling power thereof)

The problem that the present invention seeks to solve is to propose a method of controlling the operation of electronic products using a control device that cannot provide constant power.

Another problem that the present invention aims to solve is to propose a method of controlling the power supplied to the voice recognition module that constitutes the control device when necessary.

Another problem that the present invention seeks to solve is to propose a method of minimizing power consumed by the voice recognition module.

Another problem that the present invention seeks to solve is to propose a method of supplying power to the voice recognition module only when necessary.

To this end, the control device of the present invention includes a first noise filter that filters signals in a frequency band other than the set frequency band among signals received from a microphone; an amplifier that amplifies the signal received from the first noise filter; a second noise filter that filters signals in a frequency band other than the set frequency band among the signals amplified by the amplifier; a comparator that generates a trigger signal when the frequency band of the signal received from the second noise filter is a frequency band between low level and high level; When a trigger signal is received from the comparison unit, it includes a microcomputer that supplies power to the voice recognition module using a load switch.

The control device that controls electronic products according to the present invention continuously supplies power to the voice recognition module that constitutes the control device. Power is supplied to the voice recognition module only when a voice signal is received from the outside, thereby dissipating energy consumption in the control device. The power supply can be minimized. Additionally, since the control device is powered by a built-in battery and driven, there is an advantage in that the usage time of the built-in battery can be increased.

In addition, existing voice recognition modules only recognize voices from 3 to 5 meters, but the present invention can recognize voices from 7 meters or more using an amplification unit. In addition, the present invention uses Rubbish voice data as a signal to supply power to the voice recognition module.

Figure 1 shows an electronic product and a control device for controlling the electronic product according to an embodiment of the present invention.
Figure 2 is a block diagram showing the configuration of a control device according to an embodiment of the present invention.
Figure 3 is a block diagram showing the configuration of a control device according to another embodiment of the present invention.
Figure 4 is a flowchart showing operations performed in a control device according to an embodiment of the present invention.

The foregoing and additional aspects of the present invention will become more apparent through preferred embodiments described with reference to the accompanying drawings. Hereinafter, these embodiments of the present invention will be described in detail so that those skilled in the art can easily understand and reproduce them.

Figure 1 shows a control device and a control device that controls the control device according to an embodiment of the present invention. Hereinafter, using Figure 1, we will learn in detail about the control target device and the control device that controls the control target device according to an embodiment of the present invention.

Figure 1 shows a controlled device and a control device. The control device 100 includes a voice recognition module that recognizes voice, and processes the voice recognized by the voice recognition module. The control target device 200 is controlled using the voice processed by the voice recognition module. The voice recognition module must always be supplied with power to recognize voices. However, when power is always supplied to the voice recognition module, the power of the battery constituting the control device 100 is rapidly consumed due to the power supplied to the voice recognition module. Therefore, the present invention proposes a method of supplying power to the voice recognition module only when necessary. That is, the present invention proposes a method of supplying power to the voice recognition module only when the user's voice is recognized.

The control device 100 analyzes the received voice, generates a control signal, and transmits the generated control signal to the control target device 200. The control device 200 receives a control signal transmitted from the control device 100 and performs an operation corresponding to the received control signal.

Figure 2 shows a block diagram showing the configuration of a control device according to an embodiment of the present invention. Hereinafter, we will look at the configuration of the control device according to an embodiment of the present invention in detail using Figure 2.

According to Figure 2, the control device includes a microphone, a voice recognition module, a trigger signal generator, a microcomputer, and a load switch. Of course, other configurations other than those described above may be included in the control device proposed in the present invention. In particular, the control device proposed in the present invention is a device that is powered by a built-in battery instead of being constantly supplied with power.

The microphone 110 receives external sounds, and for this purpose, the microphone 110 is always supplied with power. The sound received from the microphone 110 is provided to the voice recognition module 150 and the trigger signal generator 120. In relation to the present invention, the voice recognition module 150 is not normally supplied with power, but is supplied with power by manipulating the load switch 140, and the voice recognition module 150 is driven by the supplied power. The driven voice recognition module 150 then recognizes and analyzes the sound (voice) provided from the microphone 110.

The trigger signal generator 120 analyzes the voice provided from the microphone 110 and determines whether the voice has a specific frequency band. The specific frequency band in relation to the present invention is the voice frequency band. To explain further, the voice recognition module 150 of the present invention is driven by receiving power only in the voice frequency band among various frequency bands. To this end, the trigger signal generator 120 extracts the frequency band of the sound provided from the microphone 110 and provides information about the extracted frequency band to the microcomputer 130.

The microcomputer 130 determines whether the provided frequency band is a voice frequency band, and controls the load switch 140 if it is a voice frequency band.

If the frequency band of the sound determined by the microcomputer 130 is the voice frequency band, the load switch 140 supplies power to the voice recognition module 150 to drive the voice recognition module 150. Of course, the microcomputer 130 limits (blocks) the operation of the load switch 140 when the provided frequency band is not a voice frequency band. Therefore, since the voice recognition module 150 proposed in the present invention is operated only when the sound received from the microphone 110 is a voice, the voice recognition module 150 is unnecessarily driven even when no voice is provided, resulting in the occurrence of noise. This can reduce power consumption.

Figure 3 shows a block diagram showing the configuration of a control device according to another embodiment of the present invention. Hereinafter, the configuration of a control device according to another embodiment of the present invention will be described in detail using FIG. 3.

According to Figure 3, the control device includes a microphone, a first noise filter, an amplifier, a second noise filter, a comparison unit, a microcomputer, a load switch, and a voice recognition module. Of course, other configurations other than those described above may be included in the control device proposed in the present invention.

The microphone 110 receives external sounds, and for this purpose, the microphone proposed in the present invention always receives power from the outside. The sound received from the microphone 110 is provided to the first noise filter 122 and the voice recognition module 150.

The first noise filter 122 removes noise from the sound received from the microphone 110. In relation to the present invention, the first noise filter 122 is a band pass filter (BPF) and removes signals in the remaining frequency bands except for signals in the voice frequency band.

The sound (signal) filtered by the first noise filter 122 is provided to the amplification unit 124. The amplifier 124 amplifies the sound filtered by the first noise filter to a certain distance. The amplifier 124 amplifies the sound to increase the voice recognition distance. The voice recognition distance in Far Field varies depending on the environment and sound pressure, but is generally limited to about 3m to 5m, but when using the amplifier 124, the voice recognition distance can be increased to 7m.

The sound amplified by the amplifier 124 is provided to the second noise filter 126. The second noise filter 126 functions to remove noise generated by sound amplification. The second noise filter 126 is a band pass filter (BPF) and removes signals in the remaining frequency bands except for signals in the voice frequency band. To explain further, the second noise filter 126 performs the function of removing signals in frequency bands other than 300Hz to 3.4KHz.

The sound filtered by the second noise filter 126 is provided to the comparison unit 128. The comparison unit 128 performs a trigger function by setting a high level section and a low level section. The high level and low level of the comparison unit 128 can be changed by an external control signal if necessary. To explain further, the comparison unit 128 provides information (trigger signal) about this to the microcomputer 130 when the frequency band of the sound provided from the second noise filter 126 falls between the low level and the high level. do.

When the trigger signal provided from the comparison unit is provided, the microcomputer 130 recognizes that the sound received from the microphone 110 is a voice frequency band signal. The microcomputer 130 controls the operation of the load switch 140 when the frequency band of the sound received from the microphone 110 is the voice frequency band.

After controlling the operation of the load switch 140, the microcomputer 130 limits the operation of the load switch 140 if a trigger signal is not provided within a set time from the comparison unit 128, and supplies the signal to the voice recognition module 150. Cut off the power supply. In this way, in the present invention, if a signal in the voice frequency band is not received within a set time, the power supplied to the voice recognition module 150 is cut off to minimize the power consumed by the voice recognition module 150.

The load switch 140 is driven to supply power to the voice recognition module 150 to drive the voice recognition module 150 if the frequency band of the sound recognized by the microcomputer 130 is a voice frequency band. Of course, if the trigger signal is not received from the comparison unit 128, the microcomputer 130 limits (blocks) the operation of the load switch 140 because the frequency band of the sound received by the microphone 110 is not the voice frequency band.

In relation to the present invention, the voice recognition module 150 is not normally supplied with power, but is supplied with power by manipulating the load switch 140, and the voice recognition module 150 is driven by the supplied power. The driven voice recognition module 150 then recognizes and analyzes the sound (voice) provided from the microphone 110. Therefore, since the voice recognition module 150 proposed in the present invention is operated only when the sound received from the microphone 110 is a voice, the voice recognition module 150 is unnecessarily driven even when no voice is provided, resulting in the occurrence of noise. This can reduce power consumption.

In addition, in the present invention, after the sound in the voice frequency band is received by the microphone 110, it takes a certain amount of time for the voice recognition module 150 to be supplied with power by the load switch 140. Therefore, the user of the present invention first provides a voice to drive the voice recognition module 150 through the microphone 110, and then provides a control command to control the controlled device through the microphone 110.

Figure 4 is a flowchart showing operations performed in a control device according to an embodiment of the present invention. Hereinafter, we will look in detail at the operations performed in the control device according to an embodiment of the present invention using FIG. 4.

In step S400, the microphone provides sound received from the outside to the first noise filter and the voice recognition module. Of course, it is assumed that power is not supplied to the voice recognition module in step S400.

In step S402, the first noise filter filters signals in the remaining frequency bands except for signals in the set frequency band using a band pass filter.

In step S404, the amplifier amplifies the signal filtered by the first noise filter and provides the amplified signal to the second noise filter.

In step S406, the second noise filter filters signals in the remaining frequency bands except for signals in the set frequency band using a band pass filter and then provides the signals to the comparator.

In step S408, if the frequency band of the signal provided by the second noise filter falls between the set low level and high level, the comparator generates a trigger signal and provides it to the microcomputer.

In step S410, the microcomputer determines whether a trigger signal is provided from the comparator. When a trigger signal is provided from the comparator, the microcomputer supplies power to the recognition voice module using a load switch. Additionally, if a trigger signal is not provided from the comparator within the set time, the microcomputer uses a load switch to cut off the power supplied to the voice recognition module.

In this way, the microcomputer of the present invention supplies power to the voice recognition module only when a trigger signal is provided from the comparator, thereby minimizing the power consumed by the voice recognition module and maximizing the operating time of the control device by the battery.

The present invention has been described with reference to an embodiment shown in the drawings, but this is merely illustrative, and those skilled in the art will understand that various modifications and other equivalent embodiments are possible therefrom. .

100: Control device 200: Control target device
110: Microphone 120: Trigger signal generator
130: Mycom 140: Load switch
150: Voice recognition module 122: First noise filter
124: Amplification unit 126: Second noise filter
128: Comparison part

Claims (5)

a first noise filter that filters signals in a frequency band other than the set frequency band among the voice signals provided from the microphone;
an amplifier that amplifies the signal received from the first noise filter;
a second noise filter that filters signals in a frequency band other than the set frequency band among the signals amplified by the amplifier;
a comparator that generates a trigger signal when the frequency band of the signal received from the second noise filter is a frequency band between low level and high level;
A microcomputer that supplies power to the voice recognition module when a trigger signal is received from the comparison unit; and
A voice recognition module that receives a voice signal from the microphone;
Generating a trigger signal from the first voice signal among voice signals including the first voice signal input within a certain time,
The voice recognition module receives voice signals other than the first voice signal and performs voice recognition,
The microcomputer is a control device characterized in that it controls the load switch to cut off the power supplied to the voice recognition module if a trigger signal generated from the voice signal received from the microphone is not provided within the time set by the comparison unit.
delete The control device according to claim 1, wherein the driven voice recognition module receives a signal received from the microphone.
The method of claim 3, wherein the second noise filter is:
A control device that removes signals in frequency bands other than the 300Hz to 3.4KHz frequency band, which is the voice frequency band.
The method of claim 4, wherein the comparison unit,
A control device characterized in that the low level frequency and the high level frequency are changed according to a control signal provided from the outside.