TR201702870A2 - Video display apparatus and method of operating the same. - Google Patents

Abstract

The present invention provides a video display apparatus (100) at least comprising a display screen (10), at least one loudspeaker for emitting a sound in association with at least one still or moving image displayed on the display screen (10), at least two spatially separated microphones (1, 2, 3), and an audio signal processing unit (20) configured to separate the sound emitted by the loudspeaker from a sound received by the microphones. The present invention also provides a method of operating a video display apparatus, wherein the method at least comprises displaying on a display screen of the apparatus at least one still or moving image, emitting a sound from a loudspeaker of the apparatus in association with displaying the at least one still or moving image, receiving a sound by at least two spatially separated microphones of the apparatus, and separating the sound emitted from the loudspeaker from the sound received by the microphones. Such a method allows for three- dimensional localization and separation of sound sources to receive and execute voice commands for control of a video display apparatus, such as a television, without the need for a remote control.

Description

DESCRIPTION VIDEO VIEWING APPARATUS AND THE METHODS OF OPERATING IT The present invention is a video display apparatus according to claim 1 and according to claim 12, relates to a method for operating said video display apparatus.

Background of the Invention Currently, such as televisions, video game machines and computer monitors. video display apparatus typically includes one or more of the display apparatus push button, a keyboard, keypad, joystick, and/or a touchscreen using either a defined remote control and/or a separate device such as a smartphone. electromagnetic signals such as infrared or radio waves to the instrument and apparatus sent is run. Via voice, such as voice commands, a video monitor It is difficult to operate because this type of video display apparatus is a display screen. as well as an accompaniment to, for example, a movie or television programme. image, such as movie/program music or sound effects accompanying a video game. in connection with the still or moving images shown on the screen, it is also typical also includes at least one loudspeaker that emits sound. Operation of the video display apparatus the intended sound signals are derived from these sounds emitted by the display apparatus itself. and also from echoes and background noise that are difficult to model and predict. it is difficult to distinguish.

Purpose of the Invention According to this foregoing, an object of the present invention is a video display apparatus and a relates to a method for operating the video display apparatus.

Description of the Invention The object of the present invention is to use a video display apparatus as defined in claim 1. is performed. Said video display apparatus is at least a display screen, sound associated with at least one still or moving image displayed on the image screen. emitting at least one loudspeaker, at least two spatially separated microphones and loudspeakers in a way that separates the sound emitted by the microphone from the sound picked up by the microphones. includes a configured audio signal processing unit.

This solution is useful because such a video display apparatus is a remote control. is comparatively much larger than a portable device such as a mobile phone or a smartphone, and so at least two microphones are a good way to separate sound sources from each other. far enough from each other to provide spatial analysis. can be positioned. Moreover, the audio signal processing unit, the sound emitted from the speaker, an electronic signal directly before, during or after its propagation. sound emitted by the speaker, the sound received by the microphones can be separated from sound with a high degree of precision, and echoes can be easily detected and accounted for. can participate.

Advantageous embodiments of the present invention according to any claim and/or the following can be configured according to any part of the specification.

At least one of the microphones, preferably adjacent to the video screen, is the same as the video screen. positioned facing the direction. This means that at least one of the microphones improves the odds that the screen will be facing a viewer. More preferred Therefore, at least two of the microphones must be displayed in such a way that the display screen is between them. They are positioned on both sides of the display screen and face the same direction as the display screen. This This is beneficial in terms of increasing the horizontal resolution of the microphones.

Preferably, at least one pair of at least two microphones is positionally furthest apart from each other. at least 400 mm, more preferably at least 500 mm, more preferred as such, at least 600 mm and most preferably at least 700 mm are separated. This situation advantageous because the spatial resolution of the microphones increases proportionally with distance.

According to a preferred embodiment, said at least two microphones are shaped like a triangle. Includes three microphones arranged This is beneficial because audio sources have two allows them to be separated from each other in size. For example, if the triangle has a horizontal and a If it has a vertical edge, this arrangement allows the sound sources to be oriented horizontally and vertically. will provide a suitable spatial analysis.

Preferably, the video display apparatus can also be positioned as an audio source. contains the unit. Sound source positioning unit, sound picked up by at least two microphones Based on the differences between the signals, it can determine the places of the sources of the sounds. For example, the sound source positioning unit, the locations of the sources of the sounds, a single common different times for sound from the source to reach the different ones of at least two microphones can basically determine Preferably, the video display apparatus further includes a voice recognition unit. This The case is useful because the video display apparatus is a user's voice recognition unit. choose one of the many different user profiles, according to the voice recognized by can allow. 2782ITR If this is the case, the video display apparatus can also apply a voice command. includes the unit. This is also beneficial because the video display apparatus, for example can be controlled and to do this, the apparatus must be There is no need for a separate control device such as a remote control or a smartphone.

Video viewer hands-free multimedia and gaming It also allows it to be used in applications.

According to a possible application, the video display apparatus shall be composed of at least two different fixed or mobile devices. so that the image is displayed simultaneously on the display screen. It also includes a configured, multi-view display unit. Multiple images, for example by showing different images with different polarizations from each other, at least two simultaneously on the display screen of different still or moving image. It is an existing display technology that allows In this case, suitable different large numbers of viewers with multi-view glasses with polarizations, different fixed or their own moving images without the need to split the screen can watch simultaneously. For example, a viewer is watching a movie or a television show. while another viewer is on the same display screen in a picture album. can navigate or play a video game. As is typical in such a situation, a or more viewers to the image or images watched by them can use the headphones provided with the video display apparatus for the appropriate audio signal.

If this is the case and the video display apparatus also has an audio source positioning unit and a voice command execution unit. command execution unit, from still or moving images displayed simultaneously with the corresponding and/or an audio signal produced by the video display apparatus command a related command as determined by the audio source location unit. It is arranged to apply according to the location of the sound source that gives it. This is beneficial, because a large number of viewers of the display screen are in this case one or more they can command whatever they're watching, and that's just what they're watching. affect the images and/or the audio signal they receive and does not affect its images or sound. This may cause different images to be displayed and/or adapting the corresponding audio signals to the location of the simultaneous audience also allows. For example, images related to a viewer will replace 0 viewers as they move. can follow. According to this example, if two simultaneous viewers replace each other, one of the viewers can say "I'm here" as a voice command and view the video. in this case, the displayed images and/or accompanying audio signals are accordingly can be redirected.

According to a possible application, the video display apparatus may also be a television receiver. may contain. This allows the video display apparatus to display television programs. and a separate device such as a designated remote control of the apparatus or a smartphone. It allows programs to be selected and controlled with voice commands instead of using Preferably, the audio signal processing unit reduces ambient noise by microphones. It is also configured to separate it from the received sound. This is useful because the sound source location, voice recognition, and ability to apply voice commands. can be used to improve. ambient noise from the sound picked up by the microphones separation, the speakers of the video monitor are muted and the microphones when rapid changes in the loudness of the sound picked up by otherwise it will be perceived as a user's voice, received by microphones sampling the sound and then using these samples as examples of ambient noise. can be achieved through the use of

The present invention also relates to a method of operating a video display apparatus. is relevant. This method uses at least one fixed or moving image on a display screen of the apparatus. display of the image by displaying at least one still or moving image. propagation of an associated sound from one speaker of the apparatus, positionally separated from the apparatus a sound being picked up by at least two microphones and the sound emitted by the speaker, involves separating it from the sound picked up by the microphones.

Preferably, this method uses at least one source of sound picked up by the microphones. Preferably, this method uses at least one sound in the sound picked up by the microphones. includes recognition.

If this is the case, this method can be used if a command given by at least one voice, It also includes applying the command based on the location of the sound source.

The present invention is intended to apply one or more of the methods described herein. also pertaining to a computer program product or a program code or system.

Other features, objects, and advantages of the present invention are the exemplary components of the invention. will be described below in connection with the accompanying figures shown. in line with the present invention apparatus and methods that are at least equivalent to each other in their functions components may be indicated by the same reference numbers, where the shapes of such components 2782/TR Nor do they need to be marked or described in their entirety.

The present invention is described in the following description by way of example only according to the accompanying figures. will be described.

Brief Description of Figures Figure 1 shows the different viewer relative to an image screen of a video display apparatus. is a top graphical view of their positions.

Figure 2 shows the audio signals received by stereo microphones from many different sources. It is a diagram for separation and processing.

Figure 3, displaying a video with multiple spatially separated microphones It is a graphical representation of an application of the apparatus.

Figure 4 shows multiple spatially separated microphones from a single sound source. Shows schematically a three-dimensional method of calculating distances.

Figure 5 is a schematic block for processing audio signals from two different sources. is the diagram.

Figure 6 shows audio signals from a single source by two spatially separated microphones. is a graph showing

Figure 7 is a graph showing the distribution of sound wave power by distance.

Detailed Description of the Invention Figure 1 shows the different viewer relative to an image screen of a video display apparatus. is a top graphical view of the positions (PO, P1, P2, P3). audience when in a plane equidistant between the two horizontal endpoints of the display screen (10) is found, a "good spot" as indicated by the PO position in figure 1. is in position. In this position, a spatially separated pair of microphones which are each adjacent to one of the two horizontal endpoints of the display screen (10). they will hear the same sound emitted by the audience with each other. audience, figure In all other positions, such as those indicated by P1, P2, P3 in 1, the display screen (10) at a greater distance from one of the two horizontal endpoints than the other will be found. While in these other positions, spatially separated microphones by one of the pair of images adjacent to one of the horizontal endpoints of the display screen (10). the sound received will be different from the sound received by the other of these pairs of microphones, and therefore, the sound emitted by the speaker is more effective than the ambient sound received by the microphones. It will be possible to separate.

Figure 2 is stereo from a large number of different audio sources (Source 1, Source 2, Source 3). by means of an audio signal processing unit (20) of the audio signals received by the microphones (1, 2). Shows the separation and processing schematically. Stereo microphones (1, 2), fig. 2 Generates left and right channel audio signals as shown in audio signal processing unit (20) compares these left and right channel audio signals, each of which is Source 1, Estimate 1, corresponding to one of the sounds produced by Source 2, Source 3. Estimate 2 outputs predictions called Estimate 3.

Figure 3 schematically shows an embodiment of a video display apparatus 100.

The video display apparatus 100 includes a display screen 10 and a spatially separated multiplex. contains a number of microphones (1, 2, 3). The microphones (1, 2, 3) are adjacent to the display screen. positioned and arranged in a triangular shape. The pair of microphones (1, 2) are separated from each other. positionally separated by more than 400 nm, the pair of microphones (1, 2) positionally separated by more than 500 nm, and the pair of microphones (1, 2) spatially separated by more than 600 nm.

The video display apparatus (100) has at least one fixed image displayed on the display screen (10). or several speakers to produce a sound associated with a moving picture (fig. not displayed). Video display apparatus 100, both in figure 3 also includes a television receiver, not shown, and an audio signal processing unit. Sound The signal processing unit converts the sound emitted from the speakers to the sound received from the microphones (1, 2, 3). it is arranged as it will be separated.

Figure 4 shows multiple spatially separated microphones (Mic 0, Mic 1, Mic 2, Mic 3) in one illustrates a method for calculating the three-dimensional distance to a sound source (8). This the sound source (S) according to the example is an arbitrarily defined three-dimensional Cartesian coordinate It is located in the x, y, z coordinates of the system and makes a sound at time t. Figure 4 Numerous spatially separated microphones (Mic 0, Mic 1, Mic 2, Mic 3), four different combinations of three microphones arranged in triangles. contains. mic 0; It is located at the coordinates XO, yO, 20 and the sound emitted from the S source is t0 gets it on time. Mic 1; It is located at the coordinates x1, y1, 21 and the sound emitted from the S source gets at time t1. Similarly, Mic 2; It is located at coordinates x2, y2, 22 and S receives the sound emitted from its source at time t2. Finally Mic 3; x3, y3, 23 coordinates and receives the sound emitted from the S source at time t3. Therefore Distance of Mic O from sound source (S) = (x0 - x, yO - y, 20 - z), with sound speed (0), sound A product of the difference between the time t0 received by the mic 0 and the time t emitted by the mic 0 expressed as: c*(tO - t). Similarly, the distance of Mic 1 from the sound source (S) c*(t1 - 2782ITR In t), the distance of Mic 2 from the sound source (S) as c*(t2 - t) and the distance of Mic 3 from the sound source (S) The distance (S) from the source is expressed as c*(t3 - t). So your voice is different By comparing the different times it is received on microphones (Mic O, Mic 1, Mic 2, Mic 3), the sound The location of the source in the coordinate system (x, y, z) can be calculated. Regarding Figure 4 A method of the type described as a video recording of an embodiment of the present invention. may be realized with a sound source positioning unit of the imaging apparatus.

Figure 5 shows how two different audio signals from two different audio sources can be modeled. shows it semantically. to a frequency of 10 Hz, according to the example shown in Figure 5. A first audio signal with sine1 is emitted from a first audio source and a second the audio signal cine2 is emitted from a second audio source. Just about this example sine1 and sine2 are both shown to have a sinusoidal waveform, but in practice they can have any waveform and any sound frequency or range of frequencies.

Each of sine1 and sine2 pairs of positionally separated microphones is taken by The first microphone has two amplifiers (gain1, gain2) and add1 in fig. It can be modeled with an adder shown as second microphone The amplifier can be modeled with (gain3, gain4) and a second adder designated add2.

Because the first sound source is closer to the first microphone than to the second, the sound signal sine1 passes through amplifier gain1 with a gain of k = 0.9 and the amplifier It can also be modeled as passing gain3 with only a gain of k = 0.3. Other on the other hand, because the second sound source is closer to the second microphone than to the first. the audio signal sine2 passes through amplifier gain2 with a gain of only k = 0.3, and The amplifier can also be modeled as passing through gain4 with a gain of k = 0.9. This After the amplification processes, the audio signals are sine1, as shown in figure 5. sine2 is added together by the adders (add1, add2) of each microphone.

Figure 6 shows two spatially separated microphones, each from a single common source. It schematically shows two audio signals 61, 62 received by one. given in Figure 6 The graph shows the amplitude (A) of the two audio signals (61, 62) against the x-axis, i.e. ttime shown in the abscissa. on the opposite y-axis, that is, on the ordinate. As can be seen from Figure 6, two audio signals (61, 62) have the same frequency and form a similar wave with each other. (which in this example is a sinusoidal shape), amplitude (A) of audio signal 61 audio signal It differs from that of 62 because the common source of the two signals 61, 62 is from one of the two microphones. located further away from the others.

Figure 7 schematically shows the distribution of sound wave power by distance. Figure 7 The graph given in the graph shows the amplitude A of a sound wave (71) A, one of the sound wave (71). corresponding to the distance from the source (S) to the receiver (R) and on the x-axis, i.e. it shows in the y-axis, that is, in the ordinate, against the x-distance shown in the abscissa. Figure 7 As can be seen in the amplitude (A), source (S) and its own receiver of the sound wave (71) (R) gradually decreases between Therefore, the square of the amplitude (A) of the sound wave (71) its proportional power also decreases accordingly.

Thus, this invention is, in summary, at least on a display screen, a display screen. at least one emitting a sound associated with at least one still or moving image displayed the sound emitted by the loudspeaker, at least two spatially separated microphones and the loudspeaker, an audio signal arranged to distinguish it from a sound picked up by microphones It provides a video display apparatus containing a processing unit. The present invention is a It also provides a method for operating the video display apparatus, which method at least one still or moving image on an image display of the apparatus. a sound associated with the display of at least one still or moving image. emit from one loudspeaker of the apparatus, at least two positionally separated the pickup of a sound by the microphone and the sound emitted by the speaker, involves separating it from the sound picked up by the microphones. Such a method, for example, a video display device such as a television without the need for a remote control. three of the audio sources to receive and execute voice commands to control allows them to be located and separated dimensionally.

Reference Numbers: 1, 2, 3 Spatially allocated microphones display screen audio signal processing unit Model of two audio signals 61 First audio signal 62 Second audio signal 71 sound wave 100 Video monitors A Amplitude collectors Sounds produced by sound sources estimates

Claims (1)

REQUESTS At least: a display screen (10); at least one speaker emitting a sound associated with at least one still or moving image displayed on the image screen (10); at least two spatially separated microphones (1, 2, 3; Mic 0, Mic 1, Mic 2, Mic 3); a video display apparatus (100) comprising an audio signal processing unit (20) arranged to separate the sound emitted by the loudspeaker from a sound picked up by the microphones. A video display apparatus according to claim 1, wherein at least one of the microphones (1, 2, 3; Mic O, Mic 1, Mic 2, Mic 3) is adjacent to the display screen (10) and facing in the same direction as the display screen. is positioned. A video display apparatus according to claim 1 or claim 2, wherein the at least two are positionally separated from each other by at least 400 mm. A video display apparatus according to any one of the preceding claims, wherein the at least two microphones (1, 2, 3; Mic 0, Mic 1, Mic 2, Mic 3) include three microphones arranged in a triangle. A video display apparatus according to any preceding claim further comprising an audio source positioning unit. A video display apparatus according to any one of the preceding claims further comprising a voice recognition unit. It is a video display apparatus according to claim and further comprising a voice command application unit. A video display apparatus according to any one of the preceding claims, further comprising a multi-image display unit arranged to display simultaneously at least two different still or moving images on the display screen (10). A video display apparatus according to claim 8, according to claim 7 and claim 5, wherein the voice command execution unit is associated with at least one of the corresponding still or moving images simultaneously displayed and an audio signal produced by the video display apparatus. The command is configured to execute the command relative to the location of the issuing audio source (S), as determined by the audio source positioning unit. A video display apparatus according to any one of the preceding claims further comprising a television receiver. Video display apparatus according to any one of the preceding claims, wherein the audio signal processing unit (20) furthermore; it is configured to separate the ambient noise from the sound picked up by the microphones (1, 2, 3; Mic O, Mic 1, Mic 2, Mic 3). A method for operating a video display apparatus (100) including displaying at least one still or moving image on an image display (10) of the apparatus; radiating a sound from a loudspeaker of the apparatus associated with displaying at least one still or moving image; receiving a sound by at least two spatially separated microphones (1, 2, 3; Mic 0, Mic 1, Mic 2, Mic 3) of the apparatus; and separating the sound emitted by the speaker from the sound picked up by the microphones. The method according to claim 12, further comprising determining the location of at least one source (S) of the sound received by the microphones (1, 2, 3; Mic 0, Mic 1, Mic 2, Mic 3). A method according to claim 12 or claim 13, further comprising recognizing at least one sound in sound received by microphones (1, 2, 3; Mic O, Mic 1, Mic 2, Mic 3). A method according to claim 14 in accordance with claim 13, further comprising applying a command given by at least one voice according to the location of the voice source (8) giving the command.