JP2010124391A - Information processor, and method and program for setting function - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily set a function to suit the preference of a user. <P>SOLUTION: In a television receiver 1, voice of a user is detected to detect voice information; voice information most similar to the detected voice information is retrieved from voice information registered in advance in a voice information database on the basis of each of various features; a feature corresponding to the voice information obtained as a result of the retrieval is determined to be the feature of the user; a set value of an image quality setting that suits the preference of the user having the determined feature is determined based on a value of an image quality setting that suits the preference of the user having the feature registered in advance in a setting value database for each of the various features; the image quality is set based on the determined set value; and thereby the image quality can be easily set to suit the preference of the user without requiring the user to register his or her voice in advance or specify the image quality value to be set. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an information processing apparatus, a function setting method, and a function setting program, and is suitably applied when performing various function settings of an information processing apparatus, for example.

  Conventionally, a device such as a television receiver has been controlled according to a command transmitted from the remote controller when the user operates the remote controller. However, in recent years, the number of devices that are controlled without depending on commands transmitted from such remote controllers has increased.

  For example, an apparatus has been proposed in which a voice uttered by a user is detected, the voice is analyzed and converted into a command for the device, and controlled according to the command.

Further, in such an apparatus, when a user's voice is detected, the voice is analyzed to identify the user, and based on setting values of function settings (for example, image quality setting and sound quality setting) designated in advance by the user. An apparatus for performing function setting has also been proposed (see, for example, Patent Document 1).
JP 2007-312055 A

  By the way, the above-described apparatus analyzes a voice when a user's voice is detected, and utters a voice by collating a pattern obtained as a result of the analysis with a user's voice pattern registered in the apparatus in advance by the user. Identify the user who did. And the apparatus mentioned above reads the setting value of the function setting previously designated by the specified user, and is made to perform a function setting based on the setting value.

  Therefore, in the above-described apparatus, in order to perform the function setting according to the user's preference, the user has to perform a complicated operation such as registering voice in advance and specifying the setting value of the function setting. Don't be.

  Therefore, in the above-described apparatus, it is not possible to easily perform function setting that matches the user's preference.

  The present invention has been made in consideration of the above points, and intends to propose an information processing apparatus, a function setting method, and a function setting program capable of easily performing function settings according to user preferences. .

  In order to solve such a problem, in the information processing apparatus of the present invention, a feature discrimination information detection unit for detecting feature discrimination information for discriminating a user's feature from a user, and feature discrimination information detected by the feature discrimination information detection unit Is searched for from the feature discrimination information stored in advance for each of the various features in the predetermined storage unit, and the feature corresponding to the feature discrimination information obtained as a result of the search is the user's feature. Based on a feature discriminating unit that discriminates that there is a feature, and setting value information by feature that represents a relationship between various features stored in advance in a predetermined storage unit and a setting value of a function setting that suits the user's preference having the feature A setting value determining unit that determines a setting value of the function setting that matches the user's preference having the characteristics determined by the feature determining unit, and function setting based on the setting value determined by the setting value determining unit. It was to be provided and the cormorant function setting unit.

  In this way, the present invention makes it possible to perform function settings according to user preferences without causing the user to perform complicated operations such as registering voices in advance and specifying function setting values. Can do.

  According to the present invention, it is possible to perform a function setting according to the user's preference without causing the user to perform a complicated task of registering a voice in advance and specifying a setting value for the function setting. Thus, it is possible to easily realize an information processing apparatus, a function setting method, and a function setting program that can perform function settings that meet user preferences.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The description will be given in the following order.
1. Embodiment 2. FIG. Other embodiments

<1. Embodiment>
[1-1. Internal configuration of television receiver]
FIG. 1 shows the internal configuration of the television receiver 1. In the television receiver 1, a microcomputer (also referred to as a microcomputer) 2 executes various processes in accordance with a program stored in a built-in memory (not shown) in the microcomputer 2 to control the operation of each unit. Has been made.

  The television receiver 1 detects a voice uttered by a user, analyzes the voice, converts it into a command for the television receiver 1, and is controlled according to the command.

  Specifically, when the microphone (also referred to as a microphone) 3 of the television receiver 1 detects the user's voice, the microphone 3 sends the voice to the voice information analysis unit 4 as a microphone voice signal MS.

  The voice information analysis unit 4 analyzes the microphone voice signal MS transmitted from the microphone 3 under the control of the microcomputer 2 and converts it into a command from the user.

  A known voice recognition technique can be used to convert the microphone voice signal MS into a command from the user. For example, the voice information analysis unit 4 analyzes the microphone voice signal MS to extract acoustic features, and an acoustic model (for example, a hidden Markov model) created based on average pronunciation data, or the appearance probability of a word And the sentence is recognized by collating with the language model made based on the connection probability and the like. Then, the voice information analysis unit 4 converts the sentence recognized from the microphone voice signal MS into a command from the user by comparing it with a command recorded in advance for the television receiver 1. As commands for the television receiver 1, for example, “3 channels”, “play video”, “increase volume”, etc. are used.

  Then, the voice information analysis unit 4 sends the converted command to the microcomputer 2 as the operation signal HS. The microcomputer 2 controls the operation of each unit according to the operation signal HS sent from the voice information analysis unit 4.

  Thus, the television receiver 1 is configured to control the operation of each unit in response to a voice command issued by the user.

  Furthermore, the television receiver 1 has a reception / playback function for digital broadcasting and analog broadcasting.

  Specifically, a digital broadcast signal DT or an analog broadcast signal AT received via an antenna (not shown) is sent to the tuner unit 5 under the control of the microcomputer 2. The tuner unit 5 extracts a broadcast signal of a predetermined channel (for example, a channel designated by the user via the microphone 3) from the digital broadcast signal DT or the analog broadcast signal AT under the control of the microcomputer 2. Then, the tuner unit 5 performs processing such as decoding on the extracted broadcast signal to obtain a program video signal TV and a program audio signal TA, and sends these signals to the signal control unit 6.

  The signal control unit 6 selects a predetermined signal (for example, a signal instructed to be played back by the user via the microphone 3) from various signals input to the television receiver 1 under the control of the microcomputer 2. It is made to do. Here, when the signal control unit 6 selects the program video signal TV and the program audio signal TA sent from the tuner unit 5, the signal control unit 6 sends the program video signal TV to the video processing unit 7, and the program audio signal TA to the audio processing unit. 8 to send.

  Under the control of the microcomputer 2, the video processing unit 7 extracts information on the image quality of the video based on the signal (also referred to as image quality information) from the program video signal TV sent from the signal processing unit 6. The image quality information is, for example, the pixel size of video, luminance information, color information, noise information, etc. at each pixel.

  Based on the extracted image quality information, the video processing unit 7 corrects the video based on the program video signal TV to a predetermined image quality (for example, a preset image quality). To generate a processed video signal PVS. Examples of processing for correcting image quality include sharpness correction processing, luminance correction processing, color temperature correction processing, sharpness correction processing, resolution correction processing, noise removal processing, and the like. Then, the video processing unit 7 sends the processed video signal PVS to the video display processing unit 9.

  The video display processing unit 9 performs a predetermined video display process on the processed video signal PVS sent from the video processing unit 7 under the control of the microcomputer 2 to generate a display video signal OVS. Is sent to the display 10. As a result, a video based on the display video signal OVS, that is, a program video is displayed on the display 10.

  In addition, the audio processing unit 8 controls the program audio signal TA sent from the signal control unit 6 under the control of the microcomputer 2 and outputs an audio based on the signal to a predetermined sound quality (for example, a preset sound quality). The processed sound signal PAS is generated by performing a sound processing process such as correction to the above. Then, the sound processing unit 8 sends the processed sound signal PAS to the sound output processing unit 11.

  The audio output processing unit 11 performs a predetermined audio output process on the processed audio signal PAS sent from the audio processing unit 8 under the control of the microcomputer 2 to generate an output audio signal OAS. Is sent to the speaker 12. As a result, audio based on the output audio signal OAS, that is, program audio is output from the speaker 12.

  In this way, the television receiver 1 receives digital broadcast or analog broadcast and reproduces the program video and program audio.

  Further, the television receiver 1 has a function of reproducing video and audio input from a PC by being connected to a personal computer (also referred to as a PC, not shown).

  Specifically, the television receiver 1 is connected to a PC via a PC video input terminal (not shown) and a PC audio input terminal (not shown). Then, the PC video signal PCV is input to the signal control unit 6 from the connected PC through the PC video input terminal. Further, the PC audio signal PCA is input to the signal control unit 6 from the connected PC via the PC audio input terminal.

  Here, when the signal control unit 6 selects the PC video signal PCV and the PC audio signal PCA under the control of the microcomputer 2, the signal control unit 6 sends the PC video signal PCV to the video processing unit 7 and performs audio processing on the PC audio signal PCA. Send to unit 8.

  The video processing unit 7 generates a processed video signal PVS by performing a video processing process such as correcting the PC video signal PCV sent from the signal control unit 6 to a predetermined image quality under the control of the microcomputer 2. To do. Then, the video processing unit 7 sends the processed video signal PVS to the video display processing unit 9.

  Under the control of the microcomputer 2, the video display processing unit 9 performs a predetermined video display process on the processed video signal PVS sent from the video processing unit 7 to generate a display video signal OVS. Send to display 10. As a result, an image based on the display image signal OVS, that is, an image input from the PC is displayed on the display 10.

  Also, the sound processing unit 8 performs sound processing such as correcting the PC sound signal PCA sent from the signal control unit 6 to a predetermined sound quality under the control of the microcomputer 2, thereby processing the processed sound signal PAS. Is generated. Then, the sound processing unit 8 sends the processed sound signal PAS to the sound output processing unit 11.

  Under the control of the microcomputer 2, the audio output processing unit 11 performs a predetermined audio output process on the processed audio signal PAS sent from the audio processing unit 8 to generate an output audio signal OAS, and this signal is output to the speaker. 12 to send. As a result, sound based on the output sound signal OAS, that is, sound input from the PC is output from the speaker 12.

  In this way, the television receiver 1 plays back video and audio input from a connected PC.

  Further, the television receiver 1 has a function of playing back video and audio input from the DVD playback device by being connected to a DVD (Digital Versatile Disc) playback device (not shown).

  Specifically, the television receiver 1 reproduces a DVD via a component video input terminal (not shown) and an audio input terminal corresponding to the component video input (also called a component audio input terminal, not shown). Connected with the device. Then, the component video signal CNV is input to the signal control unit 6 from the connected DVD playback device via the component video input terminal. Also, an audio signal (also referred to as a component audio signal) CNA corresponding to the component video signal CNV is input from the connected DVD playback device to the signal control unit 6 via the component audio input terminal.

  Here, when the signal control unit 6 selects the component video signal CNV and the component audio signal CNA under the control of the microcomputer 2, the signal control unit 6 sends the component video signal CNV to the video processing unit 7 and performs audio processing on the component audio signal CNA. Send to unit 8.

  The video processing unit 7 generates a processed video signal PVS by performing video processing such as correcting the component video signal CNV sent from the signal control unit 6 to a predetermined image quality under the control of the microcomputer 2. To do. Then, the video processing unit 7 sends the processed video signal PVS to the video display processing unit 9.

  The video display processing unit 9 performs a predetermined video display process on the processed video signal PVS sent from the video processing unit 7 under the control of the microcomputer 2 to generate a display video signal OVS. 10 to send. As a result, the video based on the display video signal OVS, that is, the video input from the DVD playback device is displayed on the display 10.

  In addition, the sound processing unit 8 performs sound processing such as adjusting the component sound signal CNA sent from the signal control unit 6 to a predetermined sound quality under the control of the microcomputer 2 to process the processed sound signal PAS. Is generated. Then, the sound processing unit 8 sends the processed sound signal PAS to the sound output processing unit 11.

  Under the control of the microcomputer 2, the audio output processing unit 11 performs a predetermined audio output process on the processed audio signal PAS sent from the audio processing unit 8 to generate an output audio signal OAS, and this signal is output to the speaker. 12 to send. As a result, sound based on the output sound signal OAS, that is, sound input from the DVD playback device is output from the speaker 12.

  In this way, the television receiver 1 plays back video and audio input from the connected DVD playback device.

  Further, the television receiver 1 has a function of reproducing video and audio input from the video tape reproducing device by being connected to a video tape reproducing device (not shown).

  Specifically, the television receiver 1 is connected to a video tape via a composite video input terminal (not shown) and an audio input terminal corresponding to the composite video input (also referred to as a composite audio input terminal, not shown). Connected to playback device. Then, the composite video signal CSV is input to the signal control unit 6 from the connected video tape playback device via the composite video input terminal. Also, an audio signal (also referred to as a composite audio signal) CSA corresponding to the composite video signal CSV is input to the signal control unit 6 from the connected video tape playback device via the composite audio input terminal.

  Here, when the signal control unit 6 selects the composite video signal CSV and the composite audio signal CSA under the control of the microcomputer 2, the signal control unit 6 sends the composite video signal CSV to the video processing unit 7 and performs audio processing on the composite audio signal CSA. Send to unit 8.

  The video processing unit 7 performs a video processing process such as correcting the composite video signal CSV sent from the signal control unit 6 to a predetermined image quality under the control of the microcomputer 2 to generate a processed video signal PVS. To do. Then, the video processing unit 7 sends the processed video signal PVS to the video display processing unit 9.

  The video display processing unit 9 performs a predetermined video display process on the processed video signal PVS sent from the video processing unit 7 under the control of the microcomputer 2 to generate a display video signal OVS. 10 to send. As a result, the video based on the display video signal OVS, that is, the video input from the video tape reproducing device is displayed on the display 10.

  In addition, the sound processing unit 8 performs sound processing such as correcting the composite sound signal CSA sent from the signal control unit 6 to a predetermined sound quality under the control of the microcomputer 2, thereby processing the processed sound signal PAS. Is generated. Then, the sound processing unit 8 sends the processed sound signal PAS to the sound output processing unit 11.

  Under the control of the microcomputer 2, the audio output processing unit 11 performs a predetermined audio output process on the processed audio signal PAS sent from the audio processing unit 8 to generate an output audio signal OAS, and this signal is output to the speaker. 12 to send. As a result, the audio based on the output audio signal OAS, that is, the audio input from the video tape reproducing device is output from the speaker 12.

  In this way, the television receiver 1 plays back video and audio input from the connected video tape playback device.

  Further, the television receiver 1 is connected to a USB (Universal Serial Bus) device (for example, a digital still camera or a digital video camera, not shown) to reproduce video and audio input from the USB device. It has a function to do.

Specifically, the television receiver 1 is connected to a USB device via a USB terminal (not shown). Then, the data UD recorded on the USB device is input to the decoder unit 13 from the connected USB device via the USB terminal. This data UD is, for example, JPEG (Joint Photographic Experts Group) or MPEG (Moving Picture Experts).
Group) method. The decoder unit 13 performs processing such as decoding on the input data UD, obtains the USB video signal UV and the USB audio signal UA, and sends these signals to the signal control unit 6.

  Here, when the signal control unit 6 selects the USB video signal UV and the USB audio signal UA under the control of the microcomputer 2, the signal control unit 6 sends the USB video signal UV to the video processing unit 7 and performs audio processing on the USB audio signal UA. Send to unit 8.

  The video processing unit 7 performs a video processing process such as correcting the USB video signal UV sent from the signal control unit 6 to a predetermined image quality under the control of the microcomputer 2 to generate a processed video signal PVS. To do. Then, the video processing unit 7 sends the processed video signal PVS to the video display processing unit 9.

  The video display processing unit 9 performs a predetermined video display process on the processed video signal PVS sent from the video processing unit 7 under the control of the microcomputer 2 to generate a display video signal OVS. 10 to send. As a result, an image based on the display image signal OVS, that is, an image input from the USB device is displayed on the display 10.

  In addition, the audio processing unit 8 performs audio processing such as correcting the USB audio signal UA sent from the signal control unit 6 to a predetermined sound quality under the control of the microcomputer 2, thereby processing the processed audio signal PAS. Is generated. Then, the sound processing unit 8 sends the processed sound signal PAS to the sound output processing unit 11.

  Under the control of the microcomputer 2, the audio output processing unit 11 performs a predetermined audio output process on the processed audio signal PAS sent from the audio processing unit 8 to generate an output audio signal OAS, and this signal is output to the speaker. 12 to send. As a result, sound based on the output sound signal OAS, that is, sound input from the USB device is output from the speaker 12.

  In this way, the television receiver 1 plays back video and audio input from the connected USB device.

[1-2. Image quality settings]
Further, when the television receiver 1 detects the user's voice via the microphone 3, the television receiver 1 analyzes the voice to determine the user's age group and sex, and the user's preference including the determined age group and sex is determined. It has a function to set the appropriate image quality. The image quality setting function will be described below.

  First, the process of discriminating the user's age group and gender will be described with reference to FIG. When the microphone 3 detects the voice of the user, the microphone 3 sends the voice to the voice information analysis unit 4 as a microphone voice signal MS.

  As described above, the voice information analysis unit 4 analyzes the microphone voice signal MS sent from the microphone 3, converts it into a command from the user, and sends the converted command to the microcomputer 2 as the operation signal HS. The microcomputer 2 controls the operation of each unit according to the operation signal HS sent from the voice information analysis unit 4.

  In addition, the voice information analysis unit 4 analyzes the microphone voice signal MS transmitted from the microphone 3 at this time, and determines the age group and sex of the user.

  Specifically, when the microphone sound signal MS is transmitted from the microphone 3, the voice information analysis unit 4 performs analysis such as frequency analysis and speech rate analysis on the microphone sound signal MS. Then, the voice information analysis unit 4 detects information (also referred to as voice information) indicating the acoustic features of the human voice such as frequency and speech rate from the analysis result.

  A voice information database in which voice information is registered in advance for each age group and gender is built in a built-in memory (not shown) in the voice information analysis unit 4. The voice information database includes age groups and genders statistically obtained from voice information of voices uttered by users of various ages (for example, teens, 20s, 30s, etc.) and genders (female, male). Average voice information for each is registered.

  When the voice information analysis unit 4 detects voice information from the microphone voice signal MS, the voice information analysis unit 4 compares the detected voice information with the voice information registered in the voice information database, and determines the voice information most similar to the detected voice information. Search from information database. Then, the voice information analysis unit 4 determines the age group and gender corresponding to the voice information obtained as a result of the search as being the age group and gender of the user who uttered the voice detected by the microphone 3 at this time.

  As described above, when the television receiver 1 detects a user's voice uttered as a command input, the television receiver 1 analyzes the voice and converts it into a command from the user, and controls each unit according to the command. The voice information is detected from the voice information, and the age group and the gender of the user are discriminated using the voice information.

  Then, the voice information analysis unit 4 generates user characteristic information UI using the age group parameter indicating the determined user age group and the determined gender parameter indicating the gender of the user, and sends this to the microcomputer 2.

  By the way, in the age group, for example, “1” for teens and below, “2” for 20s, “3” for 30s, “4” for 40s, “5” for 50s, “6” for 60s. ”, Those in their 70s and above are represented by an age group parameter of“ 7 ”. Further, in terms of gender, for example, a female parameter is represented by a gender parameter of “0” and a male is represented by “1”.

  Therefore, for example, the voice information analysis unit 4 sets the age group parameter to “2” when the determined user's age group is in his twenties, and sets the gender parameter to “0” when the determined user's gender is female. And Then, the voice information analysis unit 4 sends the information of the age group parameter “2” and the sex parameter “0” as the user characteristic information UI to the microcomputer 2.

  When the user characteristic information UI is input from the voice information analysis unit 4, the microcomputer 2 displays the age group and sex indicated by the user characteristic information UI, that is, the user's preference based on the age group and sex determined by the voice information analysis unit 4. Acquires the setting value of the image quality setting suitable for.

  In the built-in memory in the microcomputer 2, a setting value database in which setting values of image quality settings that suit the user's preference for each age group and sex are registered in advance for each age group and sex.

  The set value of the image quality setting registered in the set value database is, for example, statistically obtained. That is, for example, based on the result of investigating the setting value of the image quality setting that suits the user's preference for various age groups and genders, the setting of the image quality setting that suits the average user preference for each age group and sex It is guessed as a value.

  Here, the setting value of the image quality setting that suits the user's preference for each age group and gender is investigated, and the image quality setting that matches the average user's preference for each age group and gender based on the survey results. A method for estimating the set value will be described.

  First, as a method of investigating the image quality setting that suits the user's preference, for example, a method of conducting a questionnaire as to what kind of image quality setting the television receiver is normally used for a large number of users. is there. The target of the questionnaire is a user who owns the same type of television receiver as the television receiver 1.

  As a method of conducting such a questionnaire, for example, there is a method of using a television receiver connected to the Internet. First, the user connects a television receiver owned by the user to the Internet. Then, the user is caused to input the age and sex of the user to the television receiver, and specify the setting value of the image quality setting when the television receiver is normally used. Then, an answer to the questionnaire is obtained by obtaining the input age group and sex of the user and the set value of the designated image quality setting from the television receiver owned by the user via the Internet. In this way, a questionnaire about image quality setting is performed using a television receiver connected to the Internet.

  FIG. 3 shows an example of answers obtained as a result of conducting the questionnaire by the method described above. In this questionnaire, the user's age and sex, and the set values of sharpness, brightness, and color temperature are investigated as set values of image quality settings. Here, with regard to the sharpness, the set value of sharpness that is normally set is set as a reference value 1. If the numerical value is larger than 1, the image is brighter than that, and if the numerical value is smaller than 1, the image is brighter than that. This is not an image. As for the luminance, the luminance setting values that can be set by the television receiver 1 are indicated by setting values of 0 to 100, with 0 being the darkest image and 100 being the brightest image. Further, the color temperature indicates the set value of the color temperature using the absolute temperature (K), and the image becomes reddish as the color temperature is lower and becomes bluish as the color temperature is higher.

  And the example of the result of having totaled the answer of this questionnaire is shown in FIG. Here, the average value of the set values of sharpness, brightness, and color temperature is calculated for each age group and gender from the obtained questionnaire responses. Thus, the average values of the sharpness, brightness, and color temperature set values calculated for each age group and gender are set values for image quality settings that match the average user preference for each age group and gender. Infer.

  By such a method, the setting value of the image quality setting specified by the user for various age groups and genders is investigated, and the survey results are statistically matched to the average user preference for each age group and gender. The set value of the selected image quality setting.

  Then, the setting values of the image quality setting that match the user's preference for each age group and sex obtained statistically by the above-described method are registered in the setting value database for each age group and sex. The configuration of this setting value database is shown in FIG. In the setting value database, setting values for sharpness, luminance, and color temperature are registered for each age group and gender. The age group and sex are registered as an age group parameter and sex parameter used in the voice information analysis unit 4.

  The microcomputer 2 acquires the set values of the sharpness, brightness, and color temperature corresponding to the age group parameter and the sex parameter indicated by the user characteristic information UI sent from the voice information analysis unit 4 from such a set value database. Then, the microcomputer 2 assumes that these set values are set values of image quality settings that match the user's preference of the age group and sex determined by the voice information analysis unit 4.

  For example, it is assumed that the user feature information UI input from the voice information analysis unit 4 is information of age group parameter “2” and gender parameter “0”. Then, the microcomputer 2 acquires setting values of sharpness “0.80”, luminance “48.8”, and color temperature “5621” corresponding to these parameters from the setting value database shown in FIG. That is, the microcomputer 2 assumes that these set values are set values of sharpness, brightness, and color temperature that suit the preferences of users who are in their twenties and are gender female.

  As described above, the television receiver 1 has an image quality setting suitable for the user's preference of the determined age group and gender based on the set value corresponding to the determined age group and sex acquired from the setting value database in advance. Determine the setting value.

  Then, the microcomputer 2 generates a control signal GS for controlling the video processing unit 7 so as to perform image quality setting based on the setting value acquired from the setting value database, and sends this control signal GS to the video processing unit 7.

  Here, assuming that the television receiver 1 is receiving and reproducing a digital broadcast, for example, a program video signal TV is transmitted from the signal control unit 6 to the video processing unit 7. At this time, the video processing unit 7 performs a process for correcting the image quality of the video based on the program video signal TV on the program video signal TV in accordance with the control signal GS input from the microcomputer 2. That is, the video processing unit 7 performs a process for correcting the image quality of the video based on the program video signal TV on the program video signal TV based on the set value of the image quality setting that suits the user's preference. Then, as a result of this processing, the video processing unit 7 generates a processed video signal PVS and sends it to the video output unit 8.

  The video output unit 8 performs a predetermined video display process on the processed video signal PVS input from the video processing unit 7 to generate a display video signal OVS, and sends this signal to the display 10. As a result, a video based on the display video signal OVS, that is, a digital broadcast program video set to an image quality suitable for the user's preference is displayed on the display 10.

  As described above, the television receiver 1 performs image quality setting based on the set value of the image quality setting that matches the user's preference determined by the determined age group and sex, and the video set to the image quality that matches the user's preference. To the user.

  As described so far, when the television receiver 1 detects the voice of the user, the television receiver 1 analyzes the voice to detect voice information, and searches the voice information database for voice information most similar to the detected voice information. . Then, the television receiver 1 determines that the age group and sex corresponding to the voice information obtained as a result of the search are the user's age group and sex. Then, the television receiver 1 obtains the setting value of the image quality setting that matches the user's preference including the determined age group and sex from the setting value database, and performs the image quality setting based on the setting value.

  By doing so, the television receiver 1 does not require the user to perform complicated operations such as registering voice in advance and specifying the setting value of the image quality setting. It can be performed.

  Further, when the television receiver 1 detects a user's voice uttered for command input, the television receiver 1 not only controls each unit in accordance with the command obtained by analyzing the voice, but also uses the voice information. And the user's age group and gender are discriminated using the voice information.

  By doing so, the television receiver 1 can use the voice uttered for command input without using the user's utterance only to discriminate the user's age group and gender. Layer and gender can be determined. Thus, the television receiver 1 can automatically perform image quality settings that match the user's preference without causing the user to speak only to discriminate the user's age group and gender.

[1-3. Image quality setting process]
Next, a procedure of processing in which the television receiver 1 performs image quality setting that matches the user's preference (also referred to as image quality setting processing procedure RT1) will be described with reference to the sequence chart of FIG. This image quality setting processing procedure RT1 is a processing procedure executed by the microcomputer 2, the microphone 3, the voice information analysis unit 4, and the video processing unit 7 in cooperation with each other according to a program read from the built-in memory in the microcomputer 2.

  When the microphone 3 detects the voice of the user, the microphone 3 starts an image quality setting processing procedure RT1 and proceeds to step SP1.

  In step SP1, the microphone 3 sends the detected user's voice to the voice information analysis unit 4 as a microphone voice signal MS.

  When step SP1 is completed, in step SP2, the voice information analysis unit 4 analyzes the microphone voice signal MS transmitted from the microphone 3, detects voice information from the analysis result, and proceeds to step SP3.

  In step SP3, the voice information analysis unit 4 searches the voice information database for voice information most similar to the voice information detected in step SP2. Then, the voice information analysis unit 4 determines the age group and gender corresponding to the voice information obtained as a result of the search as being the age group and gender of the user who uttered the voice detected by the microphone 3 at this time. The process proceeds to step SP4.

  In step SP4, the voice information analysis unit 4 generates user characteristic information UI using the age group and gender of the user determined in step SP3, and sends them to the microcomputer 2.

  When step SP4 is completed, in step SP5, the microcomputer 2 acquires the setting value of the image quality setting corresponding to the age group and sex indicated by the user characteristic information UI from the setting value database, and proceeds to step SP6. At this time, the microcomputer 2 acquires the set value as a set value of image quality setting that matches the user's preference including the age group and sex determined by the voice information analysis unit 4.

  In step SP6, the microcomputer 2 generates a control signal GS for controlling the video processing unit 7 so as to perform image quality setting based on the setting value acquired in step SP5, and sends this control signal GS to the video processing unit 7. .

  When step SP6 is completed, in step SP7, the video processing unit 7 responds to the control signal GS sent from the microcomputer 2 for the video signal sent from the signal control unit 6 (for example, the program video signal TV). Then, a process for correcting the image quality of the video is performed. That is, the video processing unit 7 performs the image quality setting based on the setting value of the image quality setting that matches the user's preference including the age group and the gender determined by the voice information analysis unit 4.

  As a result, the television receiver 1 causes the display 10 to display an image set to an image quality that suits the user's preference of the determined age group and gender.

  In accordance with the image quality setting processing procedure RT1, the television receiver 1 determines the user's age group and gender using the detected user's voice, and the image quality suitable for the user's preference consisting of the determined age group and gender. Settings are made to do so.

[1-4. Operation and effect]
In the above configuration, when the television receiver 1 detects a user's voice uttered for command input, the television receiver 1 analyzes the voice and converts it into a command from the user, and controls each unit according to the command. . Further, the television receiver 1 detects voice information for discriminating user characteristics such as age group and sex from the voice of the user detected at this time.

  Then, the television receiver 1 searches for voice information most similar to the detected voice information from voice information registered in advance in the voice information database for each feature such as age group and sex. Then, the television receiver 1 determines that the feature corresponding to the voice information obtained as a result of the search is the feature of the user who made the detected voice.

  In the television receiver 1, setting values corresponding to the determined user characteristics are registered in advance as setting values for image quality settings that match the user's preference for each characteristic such as age group and gender. From the setting value database. The television receiver 1 assumes that this set value is a set value of an image quality setting that matches the user's preference of the age group and sex determined by the voice information analysis unit 4.

  And the television receiver 1 controls each part, and performs the image quality setting of the video displayed on the display 10 based on the acquired setting value.

  As a result, the television receiver 1 causes the display 10 to display an image set to an image quality suitable for the user's preference having the determined characteristics.

  By doing so, the television receiver 1 does not require the user to perform complicated operations such as registering voice in advance and specifying the setting value of the image quality setting. It can be performed.

  Further, when the television receiver 1 detects a user's voice uttered for command input, the television receiver 1 not only controls each unit in accordance with the command obtained by analyzing the voice, but also uses the voice information. And the user's age group and gender are discriminated using the voice information.

  By doing so, the television receiver 1 can use the voice uttered for command input without using the user's utterance only to discriminate the user's age group and gender. Layer and gender can be determined. Thus, the television receiver 1 can automatically perform image quality settings that match the user's preference without causing the user to speak only to discriminate the user's age group and gender.

  According to the above configuration, the television receiver 1 detects the voice of the user by detecting the voice of the user, and the voice information most similar to the detected voice information is registered in advance in the voice information database for each of various features. Search from voice information. Then, the television receiver 1 determines that the feature corresponding to the voice information obtained as a result of the search is the feature of the user. Then, the television receiver 1 determines the user's having the characteristic determined based on the setting value of the image quality setting that matches the preference of the user having the characteristic that is registered in the setting value database in advance for each of the various characteristics. Determine the image quality settings that suit your preferences. Then, the television receiver 1 performs image quality setting based on the determined setting value.

  By doing so, the television receiver 1 does not require the user to perform complicated operations such as registering voice in advance and specifying the setting value of the image quality setting. It can be performed. Thus, the television receiver 1 can easily perform image quality settings that suit user preferences.

<2. Other embodiments>
[2-1. Other Embodiment 1]
In the above-described embodiment, the television receiver 1 performs the image quality setting according to the user's preference having the characteristics determined from the detected user's voice.

  However, the present invention is not limited to this, and the television receiver 1 may perform various function settings (for example, sound quality settings) according to the user's preference having characteristics determined from the detected user's voice.

  For example, it is assumed that the television receiver 1 performs sound quality setting according to the user's preference having characteristics determined from the detected user's voice.

  Specifically, as shown in FIG. 1, when the microphone 3 detects a user's voice, the microphone 3 sends the voice to the voice information analysis unit 4 as a microphone voice signal MS. The voice information analysis unit 4 detects voice information from the microphone voice signal MS and uses the voice information to discriminate user characteristics. Then, the voice information analysis unit 4 generates user feature information UI based on the determined user feature and sends it to the microcomputer 2.

  At this time, in the setting value database built in the built-in memory in the microcomputer 2, various characteristics and setting values of sound quality settings that match each user's preference having each characteristic are registered in association with each other. ing. Note that the setting value of the sound quality setting registered in the setting value database is, for example, statistically obtained.

  When the user characteristic information UI is sent from the voice information analysis unit 4, the microcomputer 2 acquires a setting value of the sound quality setting corresponding to the user characteristic indicated by the user characteristic information UI from the setting value database. The microcomputer 2 assumes that this setting value is a setting value for sound quality setting that suits the user's preference having the characteristics determined by the voice information analysis unit 4.

  Then, the microcomputer 2 generates a control signal SS for controlling the sound processing unit 8 so as to perform sound quality setting based on the acquired setting value, and sends the control signal SS to the sound processing unit 8.

  Here, assuming that the television receiver 1 receives and reproduces a digital broadcast, for example, a program audio signal TA is sent from the signal control unit 6 to the audio processing unit 8. At this time, the audio processing unit 8 performs a process for correcting the sound quality of the audio based on the program audio signal TA in accordance with the control signal SS input from the microcomputer 2 with respect to the program audio signal TA. That is, the audio processing unit 8 performs a process for correcting the sound quality of the sound based on the program sound signal TA on the program sound signal TA based on the set value of the sound quality setting that suits the user's preference. Then, the audio processing unit 8 generates a processed audio signal PAS as a result of this processing, and sends it to the audio output processing unit 11.

  The audio output processing unit 11 performs a predetermined audio output process on the processed audio signal PAS input from the audio processing unit 8 to generate an output audio signal OAS, and sends this signal to the speaker 12. As a result, a sound based on the output sound signal OAS, that is, a digital broadcast program sound set to a sound quality suitable for the user's preference is output to the speaker 12.

  In this way, the television receiver 1 performs sound quality setting that suits the user's preference without performing complicated operations such as registering voice in advance and specifying sound quality setting values. be able to.

[2-2. Other Embodiment 2]
In the above-described embodiment, the television receiver 1 determines the user's age group and gender based on the detected user's voice, and performs image quality settings that match the user's preference based on the determined age group and gender. I did it.

  Not limited to this, the television receiver 1 discriminates various characteristics such as the user's emotion, physical condition, and personality from the detected user's voice, and sets the image quality that suits the user's preference having the identified various characteristics. May be performed.

  For example, it is assumed that the television receiver 1 discriminates the user's emotion from the detected user's voice, and performs image quality setting that matches the user's preference at the discriminated emotion.

  Specifically, when the microphone 3 detects the user's voice, the microphone 3 sends the voice as a microphone voice signal MS to the voice information analysis unit 4, and the voice information analysis unit 4 detects voice information from the microphone voice signal MS. In the voice information database built in the built-in memory in the voice information analysis unit 4, average voice information for each emotion (for example, excited, calm, etc.) is associated with various emotions in advance. And registered. At this time, the voice information analysis unit 4 searches the voice information database for voice information most similar to the detected voice information, and the emotion corresponding to the voice information obtained as a result of the search is the user's emotion at that time. Is determined.

  In the setting value database built in the built-in memory in the microcomputer 2, various emotions and image quality setting setting values that match the user's preference at the time of each emotion are registered in association with each other. And At this time, the microcomputer 2 acquires the setting value of the image quality setting that matches the user's preference at the time of emotion determined by the voice information analysis unit 4 from the setting value database, and performs the image quality setting based on the acquired setting value. In this manner, the television receiver 1 performs image quality settings that match the user's preferences based on the determined user's emotions.

  Similarly, the television receiver 1 discriminates various characteristics such as the user's physical condition and personality from the detected user's voice, and performs image quality setting that suits the user's preference having the identified various characteristics. May be.

[2-3. Other Embodiment 3]
Furthermore, in the above-described embodiment, the television receiver 1 analyzes the detected user's voice to detect voice information, and determines the user's characteristics using the voice information.

  Not limited to this, the television receiver 1 may detect various other information from the user and determine the user's characteristics using the information as long as the information can determine the user's characteristics. .

  For example, the television receiver 1 may determine the user's age group and gender from the user's image obtained by photographing the user using a camera or the like. In this case, the television receiver 1 is provided with, for example, a camera (not shown) for photographing the user and an image analysis unit (not shown) for discriminating the age group and sex from the user's image. To do.

  Specifically, the image analysis unit detects face information indicating facial features such as the positions of eyes, nose, and mouth from an image obtained by photographing a user's face with a camera. In the image analysis unit, a face information database is built in which average face information for each age group and gender is registered in association with the age group and gender. Then, the image analysis unit searches the face information database for face information most similar to the detected face information, and the age group and gender corresponding to the face information obtained as a result of the search are the user's age group and gender. Is determined.

  Further, for example, the television receiver 1 may determine the user's age group and sex from body temperature information obtained by detecting the user's body temperature using a thermo camera or the like. It is known that human body temperature varies with age and gender. For example, when comparing the body temperature of adult men, adult women, and infants, the body temperature of adult men is generally the lowest, the body temperature of infants is the highest, and the body temperature of adult women is intermediate between adult men and infants. Has been.

  In this case, the television receiver 1 is provided with, for example, a thermo camera (not shown) for detecting the user's body temperature and a body temperature analysis unit (not shown) for determining the age group and sex from the body temperature information. Suppose that

[2-4. Other Embodiment 4]
Further, in the above-described embodiment, the television receiver 1 sets the sharpness, brightness, and color temperature among the image quality settings that match the user's preference having characteristics determined from the detected user's voice. I made it.

  The television receiver 1 is not limited to this, and may have other image quality settings such as backlight brightness, contrast, sharpness, etc., as long as the image quality setting meets the user's preference having characteristics determined from the detected user's voice. Various image quality settings may be made.

[2-5. Other Embodiment 5]
Furthermore, in the above-described embodiment, the television receiver 1 performs image quality setting that suits the user's preference based on the setting value of image quality setting statistically obtained through a questionnaire survey or the like. .

  However, the present invention is not limited to this, and the television receiver 1 may perform image quality setting that matches the user's preference based on the setting value of the image quality setting that is generally presumed to be preferred by the user.

  For example, it is assumed that children prefer low-brightness video because they tend to watch videos with high brightness such as animation from the vicinity of television receivers, as well as visual characteristics that are sensitive to brightness. Is done. Therefore, when the microcomputer 2 of the television receiver 1 determines that the age is, for example, 10 years old or less, the luminance setting value may be lowered to set the image quality.

[2-6. Other Embodiment 6]
Furthermore, in the above-described embodiment, the television receiver 1 is configured to perform image quality settings that suit the user's preference based on the user's age group and sex determined from the detected user's voice.

  The television receiver 1 is not limited to this, and sets the image quality according to the user's preference based on, for example, information such as viewing history in addition to the user's age group and sex determined from the detected user's voice. You may do it.

  Specifically, for example, it is assumed that a viewing history database for registering viewing history is built in the built-in memory in the microcomputer 2 of the television receiver 1. For example, when the user views the same video content for 5 minutes or longer, the microcomputer 2 registers the genre of the video (for example, sports or movies) in the viewing history database.

  When the user's voice is detected via the microphone 3 in the television receiver 1, the voice information analysis unit 4 detects voice information from the user's voice and determines the user's characteristics using the voice information. Then, the microcomputer 2 acquires the setting value of the image quality setting that matches the user's preference having the characteristics determined by the voice information analysis unit 4 from the setting value database.

  Furthermore, the microcomputer 2 detects from the viewing history database the most registered video genre, that is, the most viewed video genre as the video genre preferred by the user. Then, the microcomputer 2 performs image quality setting based on the setting value acquired from the setting value database and the detected video genre. For example, when the detected video genre is a movie, the microcomputer 2 adjusts the luminance setting value acquired from the setting value database by slightly lowering the setting value, and performs image quality setting based on the adjusted setting value. It is assumed that information for adjusting the set value according to the detected video genre is also stored in the built-in memory in the microcomputer 2, for example.

  As described above, the television receiver 1 further adjusts the setting value of the image quality setting that matches the user's preference having the determined characteristics according to the user's preferred image detected from the viewing history, thereby further improving the user's preference. Can be set to suit the image quality.

[2-7. Other Embodiment 7]
Furthermore, in the above-described embodiment, the television receiver 1 acquires a setting value corresponding to the determined feature from the setting value database, and matches the preference of the user having the determined feature based on the acquired setting value. The setting value of the selected image quality setting was decided.

  The television receiver 1 is not limited to this, and the television receiver 1 matches the user's preference having the identified characteristic by an expression representing the relationship between the user's characteristic and the setting value of the image quality setting that matches the user's preference having the characteristic. The setting value of the image quality setting may be calculated and determined.

  In this case, an expression representing the relationship between the user's characteristics and the setting value of the image quality setting suitable for the user's preference having the characteristics is stored in, for example, an internal memory in the microcomputer 2.

  Further, in this case, an expression representing the relationship between the user's characteristics and the setting value of the image quality setting that suits the user's preference having the characteristics is obtained statistically, for example, as a result of questionnaire totalization shown in FIG. It can be created from the set value of the image quality setting.

  FIG. 7 is a graph showing the relationship between the age and the sharpness setting value for a male created based on the result of the questionnaire shown in FIG. In this graph, the horizontal axis indicates the age, and the vertical axis indicates the sharpness setting value. According to this graph, for example, in the teens to 40s, the sharpness tends to be set higher as the age gets higher, and in the 40s and later, the sharpness tends to be set lower as the age gets higher. . As a result, it is possible to predict what sharpness is preferred for an age for which a set value could not be obtained by a questionnaire. Therefore, it is possible to create an expression that represents the relationship between the age group and the sharpness setting value for men based on this graph.

[2-8. Other Embodiment 8]
Further, in the above-described embodiment, the present invention is applied to the television receiver 1 that is controlled in accordance with a user's voice command.

  For example, the present invention may be applied to a television receiver (not shown) controlled in accordance with an operation of a remote controller or the like.

  In this case, the television receiver has the same configuration as the television receiver 1 except that a light receiving unit (not shown) that receives an infrared signal transmitted from a remote controller is provided, for example. And

  Such a television receiver is configured to notify the user using the display 10 or the like so that the user speaks in order to determine the age group and sex of the user, for example. And when the said television receiver detects the voice uttered in order to discriminate | determine a user's age group and sex with the microphone 3, the voice information analysis part 4 will discriminate | determine a user's age group and sex using the voice. To do.

[2-9. Other Embodiment 9]
Furthermore, in the above-described embodiment, a program for executing the image quality setting processing procedure RT1 is stored in the built-in memory in the microcomputer 2.

  Not limited to this, the program may be stored in a predetermined storage medium such as a memory card or a DVD, and the microcomputer 2 may read the program from the storage medium and execute the program. In this case, it is assumed that the television receiver 1 is separately provided with a media drive that can read a program from a storage medium.

  The program may be downloaded from a predetermined server on the Internet by the microcomputer 2 and installed in a built-in memory in the microcomputer 2. In this case, it is assumed that the television receiver 1 is provided with a network interface for connecting to the Internet.

[2-10. Other Embodiment 10]
Further, in the above-described embodiment, the television receiver 1 as the information processing apparatus, the microphone 3 as the feature discrimination information detection unit, and the voice information as the feature discrimination information detection unit, the feature discrimination unit, the storage unit, and the control unit. An analysis unit 4 is provided. Further, the television receiver 1 is provided with a microcomputer 2 as a setting value determination unit, a function setting unit, a storage unit, and a control unit, and a video processing unit 7 as a function setting unit.

  Not only this but if it has the same function, you may make it comprise each function part of the television receiver 1 mentioned above with another various hardware or software.

  The present invention is not limited to this, and the present invention may be applied to other various information processing apparatuses such as a PC as long as the information processing apparatus has a similar function.

[2-11. Other Embodiment 11]
Further, the present invention is not limited to the above-described embodiment and the other embodiments 1 to 10 described so far. That is, the present invention is also applicable to a mode in which a part or all of the above-described embodiment and the other embodiments 1 to 10 described so far are arbitrarily combined, or a part of which is extracted.

  For example, other embodiments 4 and 5 may be combined. For example, it is generally predicted that a user with an older age prefers a video with a higher contrast because his / her visual acuity decreases and the text becomes difficult to read as the age increases. Therefore, for example, the microcomputer 2 of the television receiver 1 may set the image quality so that the contrast setting value increases as the determined age increases, for example, in the 40s, 50s, and 60s.

  The present invention can be effectively used widely, for example, in a television receiver capable of setting image quality and sound quality.

It is a block diagram which shows the internal structure of a television receiver. It is a basic diagram which shows the flow of the process which discriminate | determines a user's age group and sex. It is a basic diagram which shows the example of a reply of a questionnaire. It is a basic diagram which shows the example of a total result of a questionnaire. It is a basic diagram which shows the structure of a setting value database. It is a sequence chart which shows an image quality setting processing procedure. It is a basic diagram which shows the relationship between age and the setting value of sharpness.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Television receiver, 2 ... Microcomputer, 3 ... Microphone, 4 ... Voice information analysis part, 7 ... Video processing part, 10 ... Display, MS ... Microphone audio signal, HS ... Operation signal , UI: User characteristic information, GS, SS: Control signal.

Claims (8)

A feature discrimination information detection unit for detecting feature discrimination information for discriminating user features from the user;
The feature discrimination information most similar to the feature discrimination information detected by the feature discrimination information detection unit is searched from the feature discrimination information stored for each of the various features in advance in a predetermined storage unit, and the result of the search is obtained. A feature discriminating unit that discriminates that the feature corresponding to the feature discriminating information is the user's feature;
Discriminated by the feature discriminating unit based on feature-specific setting value information that represents the relationship between the various features stored in advance in a predetermined storage unit and the setting values of the function settings that suit the user's preference having the features. A setting value determining unit that determines a setting value of a function setting that meets the user's preference having the above-described characteristics;
An information processing apparatus comprising: a function setting unit configured to perform the function setting based on the setting value determined by the setting value determination unit. The feature discrimination information detection unit
The information processing apparatus according to claim 1, wherein a voice uttered by the user is detected as the feature determination information. The information processing apparatus according to claim 2, further comprising: a control unit that converts the user's voice detected by the feature discrimination information detection unit into a command and controls each unit according to the command. The feature-specific setting value information
The information processing apparatus according to claim 1, which is information obtained by statistically analyzing setting values of function settings designated by a user having various features described above. The above features
The information processing apparatus according to claim 1, wherein the information processing apparatus is age and sex. The above function settings are
The information processing apparatus according to claim 1, wherein the image quality is set for an image to be displayed on the display unit. The feature discrimination information detection unit detects feature discrimination information for discriminating the user's feature from the user,
The feature discrimination information most similar to the feature discrimination information detected by the feature discrimination information detection unit is searched from the feature discrimination information stored for each of the various features in advance in a predetermined storage unit, and the result of the search is obtained. The feature discriminating unit discriminates that the feature corresponding to the feature discriminating information is the user's feature,
Discriminated by the feature discriminating unit based on feature-specific setting value information that represents the relationship between the various features stored in advance in a predetermined storage unit and the setting values of the function settings that suit the user's preference having the features. The setting value determination unit determines a setting value of the function setting that suits the user's preference having the above-described features,
A function setting method in which the function setting unit performs the function setting based on the setting value determined by the setting value determination unit. On the computer,
A step of detecting the feature discrimination information for discriminating the user's feature from the user by the feature discrimination information detection unit;
The feature discrimination information most similar to the feature discrimination information detected by the feature discrimination information detection unit is searched from the feature discrimination information stored for each of the various features in advance in a predetermined storage unit, and the result of the search is obtained. A feature discriminating unit discriminating that the feature corresponding to the feature discriminating information is the user's feature;
Discriminated by the feature discriminating unit based on feature-specific setting value information that represents the relationship between the various features stored in advance in a predetermined storage unit and the setting values of the function settings that suit the user's preference having the features. A setting value determining unit determining a setting value of a function setting that suits a user's preference having the above-described characteristics;
A function setting program for causing the function setting unit to execute the function setting based on the setting value determined by the setting value determining unit.

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