KR101104028B1 - Mobile terminal of controlling vibration quantity using self-recognition and control method for vibration quantity of mobile terminal using self-recognition - Google Patents

Abstract

PURPOSE: A mobile communication terminal for controlling the amount of vibration and vibration controlling method are provided to generate optimum vibration amount without giving inconvenience to a user. CONSTITUTION: In case a mobile communication terminal set up as a vibration mode, a vibration generator(100) generates vibration. An initial vibration level generating unit(200) generates initial vibration level data of the vibration generator. A standard vibration level decision unit(300) generates standard vibration level data about the mobile communication terminal. A vibration controller(400) controls the vibration generator in order to change the vibration level of the mobile communication terminal as a standard vibration level.

Description

MOBILE TERMINAL OF CONTROLLING VIBRATION QUANTITY USING SELF-RECOGNITION AND CONTROL METHOD FOR VIBRATION QUANTITY OF MOBILE TERMINAL USING SELF- RECOGNITION}

The present invention relates to a mobile communication terminal for adjusting the vibration amount and a method for adjusting the vibration amount in the mobile communication terminal. In particular, the present invention relates to a mobile communication terminal and a vibration control method for adjusting the amount of vibration so that the user of the mobile communication terminal can be aware through the self-recognition of the mobile communication terminal, or to adjust the amount of vibration according to the surrounding environment.

The mobile communication terminal may be set to vibrate a notification for receiving a call or receiving a message according to an environment in which the mobile communication terminal is used or a user's request.

Conventional mobile communication terminals have a constant vibration intensity. Therefore, the mobile communication terminal generates a vibration of a constant intensity regardless of the place where it is used. In some cases, this may cause more vibration than necessary to cause discomfort to surrounding people, and on the contrary, it may be difficult to use a mobile communication terminal by generating a vibration that is too small for a user to detect.

For example, a problem occurs when the mobile terminal generates a vibration more than necessary in a quiet theater or the like, even when placed on a material that absorbs vibration, such as a sofa, and the user cannot detect the same vibration.

Efforts have been made to solve such a problem, but the conventional methods are merely a method of controlling the amount of vibration and a ring tone by estimating the surrounding situation, and thus are insufficient as a method of controlling the vibration generated by the mobile communication terminal itself. For example, the conventional method does not distinguish between the case where the mobile communication terminal is on a soft bed and the case where the user is on a hard desk.

Mobile communication terminal for controlling the amount of vibration through the self-recognition according to the present invention and a method for controlling the amount of vibration through the self-recognition in the mobile communication terminal for the purpose of the following problems.

First, when vibration occurs in a mobile communication terminal, it is intended to generate an optimal amount of vibration for the user to recognize without causing discomfort to the surroundings according to the environment in which the mobile communication terminal is used.

Second, in the mobile communication terminal to measure the noise or illuminance according to the environment in which the mobile communication terminal is located to generate the optimal amount of vibration suitable for the surrounding environment.

Third, it is intended to generate an optimal amount of vibration that a user can recognize according to the environment in which the mobile communication terminal contacts.

Fourth, in the mobile communication terminal, the optimum vibration amount is generated in consideration of all variables such as actual vibration amount, ambient noise, and illumination of the mobile communication terminal.

The solution to the problem of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

The mobile communication terminal for controlling the vibration amount through self-recognition according to the present invention, when the mobile communication terminal is set to the vibration mode, the vibration generating unit for generating a vibration, the initial vibration level data of the initial vibration level generated in the vibration generating unit Initial vibration level generation unit for generating, standard vibration level generation unit for generating standard vibration level data for the mobile communication terminal, and when the standard vibration level data and the initial vibration level data are different, the vibration level of the mobile communication terminal is changed to the standard vibration level. It includes a vibration control unit for controlling the vibration generating unit to change.

The initial vibration level generating unit according to the present invention includes any one or more of a vibration amount measuring module, a noise measuring module or an image measuring module.

Initial vibration level generating unit according to the present invention initial control to control the operation of one or more of the vibration amount measurement module, noise measurement module or image measurement module according to the environmental factors including any one or more of the noise factor, illuminance factor or image change factor The apparatus further includes a vibration amount measurement control unit.

The initial vibration level generating unit according to the present invention is characterized in that at least one of the vibration amount measuring module, the noise measuring module or the image measuring module operates according to an input value or a predetermined value.

The vibration amount measuring module according to the present invention is characterized in that when vibration occurs in the vibration generating unit, the initial vibration level data is generated by measuring the vibration amount of the mobile communication terminal itself.

The noise measuring module according to the present invention measures the initial vibration level data by measuring one or more of the amount of noise generated by the mobile communication terminal itself or the vibration noise ratio of the mobile communication terminal compared to the ambient noise when the vibration occurs in the vibration generating unit. It is characterized by generating.

The image measuring module according to the present invention is characterized in that when vibration occurs in the vibration generating unit, the initial vibration level data is generated by measuring focal shake of the surrounding image due to the vibration.

The standard vibration level data generated by the standard vibration level generating unit according to the present invention is characterized in that it is a value set in advance or a value set according to the surrounding environment of the mobile communication terminal.

Vibration generating unit according to the invention is characterized in that for generating vibration at the last vibration level.

The vibration generating unit according to the present invention further includes an illuminance sensor, and when there is no change in illuminance by comparing the illuminance at the time of immediately preceding vibration with the illuminance sensor, the vibration is generated at the immediately preceding vibration level.

The vibration generating unit according to the present invention further includes a noise sensor, and when the noise level is not changed by comparing the current amount of noise with the amount of noise at the previous vibration time using the noise sensor, generating vibration at the immediately preceding vibration level. It is done.

In the mobile terminal according to the present invention, the method for controlling the amount of vibration through self-recognition is performed in step S1, in which data for an initial vibration level, which is a vibration level at the time of vibration generation in the mobile communication terminal, is generated. S2 step of generating the standard vibration level data and S3 step of changing the vibration level of the mobile communication terminal to the standard vibration level when the standard vibration level data and the initial vibration level data generated in step S2 are different.

Initial vibration level data generated in step S1 according to the present invention is characterized in that it is generated through the initial vibration amount measurement unit including any one or more of the vibration measurement module, noise measurement module or image measurement module.

Initial vibration measurement unit according to the present invention is characterized in that any one or more of the vibration measurement module, noise measurement module or image measurement module according to the environmental factors including any one or more of the noise factor, illuminance factor or image change factor. It is done.

The initial vibration amount measuring unit according to the present invention is characterized in that at least one of the vibration amount measuring module, the noise measuring module or the image measuring module operates according to an input value or a predetermined value.

Vibration amount measuring module according to the invention is characterized in that for measuring the vibration energy of the mobile communication terminal when the vibration occurs in the vibration generating unit.

The noise measuring module according to the present invention is characterized in that when vibration occurs in the vibration generating unit, one or more of the amount of noise generated in the mobile communication terminal itself due to the vibration or the vibration noise ratio of the mobile communication terminal compared to the ambient noise.

The image measuring module according to the present invention is characterized in that when the vibration occurs in the vibration generating unit, the focus shake of the surrounding image due to the vibration is measured.

Standard vibration level data generated in step S2 according to the present invention is characterized in that the value is set in accordance with the pre-input value or the surrounding environment of the mobile communication terminal.

The vibration of the mobile communication terminal generated in step S1 according to the present invention is characterized in that the vibration of the previous vibration level is generated.

In the step S1 according to the present invention, when the current illuminance and the illuminance at the last vibration point are compared and there is no change in the illuminance, the vibration of the immediately preceding vibration level is generated.

In the step S1 according to the present invention, when the noise level does not change by comparing the current amount of noise with the amount of noise at the previous vibration time, the vibration is generated at the previous vibration level.

The method of controlling the vibration amount through the self-recognition in the mobile communication terminal and the mobile communication terminal for controlling the vibration amount through the self-recognition according to the present invention has the following effects.

First, the mobile communication terminal itself controls the amount of vibration in accordance with the surrounding environment to provide a mobile communication terminal having an optimal amount of vibration.

Second, the vibration level is adjusted to an optimal vibration level by measuring the vibration amount of the actual mobile communication terminal vibrating through the vibration measurement module.

Third, the mobile communication terminal measures the amount of noise due to vibration of the mobile communication terminal through the noise measurement module to adjust the vibration level to an optimal vibration level.

Fourth, the mobile communication terminal measures the vibration of the image input to the camera through the image measuring module to adjust the vibration level to the optimal vibration level.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a block diagram of the configuration of a mobile communication terminal for adjusting the amount of vibration through self-recognition according to the present invention.
2 is a layout diagram schematically showing an example of the configuration of the initial vibration level generating unit 200 disposed in the mobile communication terminal according to the present invention.
3 is a block diagram showing the configuration of the initial vibration measurement unit 210.
4 is a table showing an example of conditions under which standard vibration level data is constructed.
5 is a flowchart illustrating a method for adjusting the amount of vibration through self-recognition in a mobile communication terminal according to the present invention.
6 is a flowchart of the vibration amount control through the self-recognition of the present invention.

Hereinafter, with reference to the drawings will be described in detail with respect to a mobile communication terminal for adjusting the amount of vibration through self-recognition according to the present invention and a method for adjusting the amount of vibration through self-recognition in the mobile communication terminal.

1 is a block diagram of the configuration of a mobile communication terminal for adjusting the amount of vibration through self-recognition according to the present invention.

In the mobile communication terminal for adjusting the vibration amount through self-recognition according to the present invention, when the mobile communication terminal is set to the vibration mode, the initial vibration level generated by the vibration generating unit 100 and the vibration generating unit 100 to generate vibrations. Initial vibration level generator 200 for generating initial vibration level data of the standard, Standard vibration level generator 300 for generating standard vibration level data for the mobile communication terminal and the standard vibration level data is different from the initial vibration level data In this case, the vibration control unit 400 controls the vibration generating unit 100 to change the vibration level of the mobile communication terminal to the standard vibration level.

The vibration generating unit 100 is configured to generate vibration in the mobile communication terminal when a call is received or an SMS message is received when the mobile communication terminal is set to the vibration mode. As a configuration that can be devised by those skilled in the art, it can be implemented in various forms including a motor.

In the following description of the present invention, the vibration level generated by the vibration generating unit 100 is expressed in units that can be intuitively recognized as vibration levels 1, 2, 3, .. do. Actual vibration energy may be expressed in various units or equations used in the field of physics. The noise level to be described later is also expressed as a level expressed as an integer rather than a unit such as db.

Hereinafter, the vibration level means a specific physical vibration amount, and the vibration level data is defined as data having a numerical meaning that can be processed in the present invention as a digital or analog signal.

If there is no change in the vibration level of the user, the vibration generating unit 100 preferably generates initial vibration at the vibration level generated just before. If the surrounding environment has not changed, the previous vibration level is still the most suitable vibration level. Details will be described later.

The initial vibration level generating unit 200 is configured to measure the vibration level of the initial vibration in the vibration generating unit 100 when the mobile communication terminal is set to vibration. The initial vibration level generating unit 200 generates initial vibration level data, which is data about the initial vibration level.

The initial vibration level generating unit 200 preferably includes an initial vibration measurement unit 210 including any one or more of the vibration measurement module 211, the noise measurement module 212, or the image measurement module 213. Do. In addition, it is obvious that various configurations can be used by those skilled in the art that can be replaced with a configuration for measuring vibration amount.

Initial vibration level Generator

2 is a layout diagram schematically showing an example of the configuration of the initial vibration level generating unit 200 disposed in the mobile communication terminal according to the present invention. In the mobile communication terminal, a vibration measurement module, a noise measurement module 212, and an image measurement module 213 for measuring vibration of the mobile communication terminal itself are illustrated. The vibration measuring module may not be protruded to the outside or may be configured to be mounted inside. However, the speaker of the noise measuring module 212 and the camera of the image measuring module 213 may be mounted outside the mobile communication terminal. In particular, in the case of a camera, it is preferable that the lens portion of the camera has a shape that is necessarily observed outside the mobile communication terminal. 2 illustrates a case where each configuration is installed one by one, the initial vibration amount measuring unit 210 may be one or more of each configuration, the location disposed in the mobile communication terminal may be variously changed.

3 is a block diagram showing the configuration of the initial vibration measurement unit 210. Each structure is demonstrated below.

The vibration amount measuring module 211 generates initial vibration level data by measuring the vibration amount of the mobile communication terminal itself when vibration occurs in the vibration generating unit 100. It is to measure the vibration energy generated by vibration in the mobile communication terminal itself. The vibration amount measurement module 211 includes a vibration amount measurement sensor 211a for measuring the vibration amount and a vibration data generator 211b for converting the measured vibration amount into a digital or analog signal.

The vibration generated from the vibration generating unit 100 generates vibration with a constant intensity according to the set level, but the actual vibration amount (vibration energy) may vary according to the environment in which the mobile communication terminal is located.

For example, assuming that the vibration generating unit 100 generates vibration at a vibration level of 3, the mobile communication terminal is placed on a soft object (bed, pocket of clothes, etc.) that can absorb vibration energy, or another object in a bag. In a situation where vibration cannot be transmitted to the outside by being pressed by the field, the vibration level of the mobile communication terminal itself may be 1 or 2 less than 3. In this case, since the actual vibration level is low, the user does not recognize the vibration of the mobile communication terminal and thus does not recognize the incoming call.

The opposite is also possible. For example, assuming that the vibration generating unit 100 generates vibration at a vibration level of 3, the mobile communication terminal may have a greater vibration energy while colliding with a hard desk in a situation where the mobile communication terminal is located on a desk of a hard material. . That is, the mobile communication terminal may have a vibration level of 4 or 5. In this case, since a vibration amount higher than the intended vibration amount is generated, it may cause discomfort to the surroundings.

Therefore, the vibration amount measuring module 211 generates the initial vibration level data by measuring the vibration amount of the mobile communication terminal itself when vibration occurs in the vibration generating unit 100.

When the vibration measuring unit 212 vibrates in the vibration generating unit 100, the initial vibration is measured by measuring one or more of the amount of noise generated by the mobile communication terminal itself or the vibration noise ratio of the mobile communication terminal compared to the ambient noise due to the vibration. Level data can be generated.

The present invention uses the noise measurement module 212 as another means for measuring the amount of vibration generated in the mobile communication terminal. Only the amount of noise due to vibration generated in the vibration generating unit 100 (first noise amount) may be measured, and the amount of vibration noise (second noise amount) compared to ambient noise may be measured.

The noise measurement module 212 includes a microphone 212a, an ambient noise reduction filter 212b, and a noise-vibration data generator 212c to measure only the first noise amount. The ambient noise removing filter 212b is used to measure only noise caused by vibration of the mobile communication terminal in the ambient noise. The ambient noise removal filter 212b is widely used in the field of computer speech processing, and is configured to remove the remaining sound while leaving only noise of a specific frequency caused by vibration of the mobile communication terminal. The noise-vibration data generator is configured to data measured noise into a digital or analog signal.

In order to measure the second noise level, the noise measurement module 212 further includes a noise ratio calculator for noise ratio calculation. It may have a separate configuration or may be configured together with the noise-vibration data generator. 3 is not shown in a separate configuration.

As described above, the amount of vibration noise of the mobile communication terminal is measured, and the ambient noise is measured at once without a filter applied, and then the vibration noise ratio to the ambient noise is calculated. Through this, you can see how much noise is perceived by the user compared to the current surroundings.

For example, if a user holds a mobile terminal in his hand or puts it in his pocket, the user feels and recognizes vibration. However, if the mobile terminal is placed in a handbag or other object, the user may feel the noise generated by the vibration. Receive a call, etc. Therefore, in this case, the vibration noise to noise ratio is an important factor in determining the vibration amount of the mobile communication terminal.

Whether the first noise level or the second noise level is measured depends on the environment in which the mobile communication terminal is located. A detailed process for selecting this will be described later.

When vibration is generated in the vibration generating unit 100, the image measuring module 213 may generate initial vibration level data by measuring focal shake of the surrounding image due to the vibration. The image measuring module 213 is a camera 213a for capturing an image around a mobile communication terminal and an image-vibration data generator 213b that measures the shaking of an image input to the camera 213a and converts the image into a digital or analog signal. It includes.

The camera used in the image measuring module 213 may use a digital camera and a lens that are basically installed in the mobile communication terminal. In the case of the image measuring module 213, the camera should be operated in an environment where camera photography is possible. Therefore, there should be incident light that can take camera shots by measuring illuminance of the camera lens in advance. If the image captured by the camera includes various surrounding images, it is possible to measure the shaking of the focus due to the vibration. However, if the image being photographed has a single color background, it may be difficult to detect the background because there is no change in the background even if it is shaken by vibration. In this case, it is preferable not to use the image measuring module 213, and specific operating conditions will be described later.

The image-vibration data generator 213b of the image measuring module 213 may be implemented using techniques available to those skilled in the art of computer image processing. The vibration of the image may be measured by analyzing the continuously input images by analyzing the movement of the feature points in a predetermined distance or a moving distance of the feature points forming a line. It is a matter of course that the shaking of the image can be measured by a technique which can be used by those skilled in the art.

The initial vibration level generating unit 200 measures the vibration amount measurement module 211 included in the initial vibration amount measuring unit 210 according to an environmental factor including at least one of a noise factor, an illuminance factor, and an image change factor, and noise measurement. It is preferable to further include an initial vibration amount measurement control unit 220 for controlling at least one of the module 212 or the image measurement module 213 to operate.

The initial vibration amount measurement unit 210 may include one or more of the vibration amount measurement module 211, the noise measurement module 212, or the image measurement module 213. It is possible to measure the vibration amount with only one module, but it is preferable to use each module in a combined form to measure the vibration amount more accurately according to the surrounding environment of the mobile communication terminal.

If the initial vibration amount measurement unit 210 is composed of only one module, the initial vibration amount measurement control unit 220 may not be necessary.

When the vibration amount measuring module 211, the noise measuring module 212, or the image measuring module 213 is used in combination, it must be controlled according to which environment each module operates. Controlling this is the initial vibration amount measurement control unit 220.

The surrounding environment is defined as an environmental factor so that the initial vibration amount measurement control unit 220 can analyze the elements to be represented. Important environmental factors in the present invention are changes in noise, illumination and image. These are called subfactors of environmental factors and are defined as noise factors, illuminance factors, and image change factors, respectively. The initial vibration amount measurement control unit 220 controls how each module of the initial vibration amount measurement unit 210 operates by analyzing each sub-factor.

The most efficient module for the vibration amount measurement may be the vibration amount measurement module 211. This is because the vibration amount of the actual mobile communication terminal can be measured under any circumstances. Therefore, it is preferable that the normal vibration amount measuring module 211 operates and additionally, another module operates.

The noise measurement module 212 measures a noise level (first noise amount) due to vibration of the mobile communication terminal itself using a filter. If the ambient noise is very loud, the first noise amount may not be measured accurately even if the filter is used. Can be. In a stadium, a crowded train station or a crowded crowd, or near an airport with frequent takeoffs and landings, the noise measurement module 212 may be difficult to measure an accurate first noise level. In addition, even if the ambient noise level is not always large, it may be difficult to measure the first noise amount even when a large amount of ambient noise occurs when receiving a call.

Therefore, it is preferable to set the noise measurement upper limit condition in which the noise measurement module 212 can operate correctly, and determine whether to operate the noise measurement module 212. Since the noise measurement upper limit condition may vary depending on the performance of the actual noise measurement module 212, it is preferable to set an optimum noise measurement upper limit condition in advance according to the noise measurement module 212.

After measuring the ambient noise of the mobile communication terminal using the microphone of the noise measurement module 212, by measuring the first noise amount by applying a filter, and measuring the vibration noise of the mobile communication terminal compared to the ambient noise amount (second Noise level). The second noise level may be used to generate the standard vibration level data to be described later, rather than being used by the initial vibration amount measurement control unit 220.

The image measuring module 213 is a module for measuring the amount of vibration due to the shaking of the input image. Basically, the camera should have a condition for capturing the surrounding image. In the case where the ambient light is low, an infrared camera capable of capturing a nighttime image may be used. However, if it is assumed that the camera is a general camera and the image is difficult due to low ambient light, it is preferable to basically not use the image measuring module 213. .

Therefore, it is preferable to determine whether the operation of the image measuring module 213 is set by setting an upper limit image measuring condition capable of capturing an image in a manner similar to the noise measuring module 212 described above. The upper limit of the image measurement condition may vary depending on the performance and the type of the camera.

In the case of the image measurement module 213, one more situation should be considered. When the image input to the camera is a background of the same color, it is very difficult to measure the shake of the image. Therefore, if shaking of the image input to the camera is not detected at all despite the vibration, it is preferable not to use the image measuring module 213. This is called image change factor.

The shaking of the image may be determined by the image-vibration data generator 213b. That is, if the initial vibration amount measurement control unit 220 generates data indicating that the shaking of the image does not appear at all in the image-vibration data generator 213b, the initial vibration amount measuring control unit 220 does not use the data generated by the image measuring module 213 and no longer uses the image. The measurement module 213 controls not to operate.

In another embodiment, at least one of the vibration amount measuring module 211, the noise measuring module 212, or the image measuring module 213 is operated by the initial vibration amount measuring unit 210 according to an input value or a predetermined value. May be That is, one or more combination modules of each module of the initial vibration amount measuring unit 210 may be used according to a value input by a user of the mobile communication terminal or a preset value.

Standard vibration level data

The standard vibration level generating unit 300 generates standard vibration level data to be compared with the initial vibration level data. Standard vibration level data should be prepared in advance in consideration of various conditions and cases. Since the standard vibration level data is data used in the vibration control unit 400 and must be predefined and prepared, the standard vibration level data is preferably stored in the memory unit 500 of the mobile communication terminal. The memory unit 500 may be a separate configuration or may be a configuration included in the vibration control unit 400.

In one embodiment, the standard vibration level may be a vibration level preset by the user without considering the surrounding environment in which the mobile communication terminal is currently located. That is, if the user sets the vibration level of 3, the standard vibration level is also set to 3. The standard vibration level generating unit 300 generates the standard vibration level data corresponding to the standard vibration level 3 and transmits it to the vibration control unit 400 or the standard generated by the standard vibration level generating unit 300 in the memory unit 500. The vibration level data is stored.

In another embodiment, the standard vibration level may be set in consideration of the environment in which the mobile communication terminal is located. There are two main environmental factors to consider when establishing a standard vibration level. Noise and illumination around the mobile terminal. What the noise and illuminance mean is already described above in the description of the initial vibration amount measurement control unit 220.

As the noise used herein, the second noise amount generated by the noise measurement module 212 may be used. Alternatively, it may be used to measure only ambient noise.

4 is a table showing an example of conditions under which standard vibration level data is constructed. For convenience, the intensity and noise intensity are divided into High, Middle, and Low, but more detailed classification is possible.

If the noise and light are strong, it can be assumed that the surrounding area is noisy in daylight or bright lighting. In this case, the vibration level may be set upward by one level or two levels higher than the vibration level set by the user, and the vibration level may be automatically set in consideration of noise and illuminance. In FIG. 4, it is expressed by a method of adding or subtracting from a level set by a user. That is, when both the noise and the illuminance are high, the vibration level of +2 steps becomes the standard vibration level than the vibration level set by the user. The table shown in FIG. 4 is set to consider noise factors more importantly than illuminance.

Although it is possible to simply set the vibration level in advance through an algorithm, it is desirable to determine the most optimal vibration level in advance through various experiments according to the surrounding environment and use it as the standard vibration level.

If the noise and light are low, it can be assumed that it is a dark place such as a night or a movie theater and a quiet place around. In this case, the vibration level set by the user may be set to one or two levels lower than the vibration level, and may be automatically set to an optimal vibration level in consideration of ambient noise and illuminance.

The table shown in FIG. 4 corresponds to an example of standard vibration level data according to the present invention. It is desirable to generate the standard vibration level data in advance through experiments on the optimal vibration level in various environments in which actual mobile communication terminals are used.

Furthermore, by using a gyro sensor and / or an acceleration sensor in addition to the noise and illuminance, the standard vibration level may be set in consideration of whether the user carries the mobile communication terminal.

As a result, the standard vibration level data generated by the standard vibration level generator 300 is a value input in advance or set according to the surrounding environment of the mobile communication terminal.

When the standard vibration level data is generated and prepared by the standard vibration level generator 300, and the initial vibration level data is generated by the initial vibration level generator 200, the vibration controller 400 generates the initial vibration level data and the standard vibration level. By comparing the data, if the initial vibration level data and the standard vibration level data are different, the vibration amount is adjusted so that the vibration level of the mobile communication terminal is equal to the standard vibration level.

Except when the surrounding environment of the mobile communication terminal is suddenly changed, the surrounding environment of the mobile communication terminal is usually equal to a certain time. Therefore, if the vibration level of the mobile communication terminal is changed to be equal to the standard vibration level immediately before, the next vibration is preferably generated with the vibration level that was changed just before.

As an embodiment for this purpose, the vibration generating unit 100 may generate a vibration at the immediately preceding vibration level when there is no change in the illumination by comparing the current illumination with the illumination at the last vibration point.

As another embodiment, the vibration generating unit 100 may generate a vibration at the immediately preceding vibration level when there is no change in the amount of noise by comparing the current amount of noise with the amount of noise at the previous vibration point using a noise sensor.

As another embodiment, the vibration generating unit 100 is a race having no change in movement compared to the current movement and the movement of the immediately preceding vibration time by using a gyro sensor and / or acceleration sensor that can detect the movement of the mobile communication terminal. The vibration may be generated at the vibration level immediately before.

If there is a change in illuminance, noise, or movement of the immediately preceding vibration point, the vibration may be generated at a vibration level set by the user instead of the immediately previous vibration level. Most preferably, the vibration is generated at the optimum vibration level in consideration of the surrounding environment of the mobile communication terminal from the beginning. In this case, the reference available may be the above-mentioned standard vibration level data.

However, by measuring the illuminance, noise, or movement of the mobile communication terminal to generate the vibration at the vibration level 2, the actual amount of vibration of the mobile communication terminal itself is output to the vibration level 1 depending on the physical environment in which the mobile communication terminal is located. Can be. Accordingly, the above-described configurations of the initial vibration amount level generating unit have a meaning.

Hereinafter, a method of adjusting the amount of vibration through self-recognition in the mobile communication terminal will be described. However, the parts common to the mobile communication terminal for adjusting the vibration amount through the above-described self-recognition will be omitted and only the characteristic parts will be mainly described.

5 is a flowchart illustrating a method for adjusting the amount of vibration through self-recognition in a mobile communication terminal according to the present invention.

In the mobile terminal according to the present invention, the method for controlling the amount of vibration through self-recognition is performed in step S1, in which data for an initial vibration level, which is a vibration level at the time of vibration generation in the mobile communication terminal, is generated. S2 step of generating the standard vibration level data and S3 step of changing the vibration level of the mobile communication terminal to the standard vibration level when the standard vibration level data and the initial vibration level data generated in step S2 are different.

The initial vibration level data generated in step S1 may be generated through the initial vibration amount measurement unit 210 including any one or more of the vibration amount measurement module 211, the noise measurement module 212, or the image measurement module 213. Can be.

The initial vibration amount measurement unit 210 may measure the vibration amount measurement module 211, the noise measurement module 212, or the image measurement module 213 according to an environmental factor including at least one of a noise factor, an illuminance factor, and an image change factor. Any one or more of these may operate.

In another embodiment, the initial vibration amount measuring unit 210 operates one or more of the vibration amount measuring module 211, the noise measuring module 212, or the image measuring module 213 according to an input value or a predetermined value. You may.

When the vibration amount measuring module 211 generates vibration in the vibration generating unit 100, and measures the vibration energy of the mobile communication terminal itself, and the noise measuring module 212 when the vibration occurs in the vibration generating unit 100, Measures at least one of the amount of noise generated by the mobile communication terminal itself due to vibration or the noise ratio of the vibration of the mobile communication terminal to the ambient noise, and the image measuring module 213 vibrates when the vibration is generated in the vibration generating unit 100. Measure the focal shake of the surrounding image.

The standard vibration level data generated in step S2 is "pre-input value" or "value set according to the surrounding environment of the mobile communication terminal". It is desirable to prepare in advance to a value that is actively set according to the surrounding environment of the mobile communication terminal.

The vibration of the mobile communication terminal generated in step S1 is preferably the vibration of the last vibration level.

 Step S1 compares the current illuminance with the illuminance at the last vibration point and when there is no change in illuminance, vibration of the immediately preceding vibration level is generated, or step S1 uses the noise sensor to compare the amount of noise with the noise level at the immediately preceding vibration point. If there is no change, the vibration can be generated at the immediately preceding vibration level.

6 is a flowchart of the vibration amount control through the self-recognition of the present invention.

When the mobile communication terminal is set to the vibration mode (S501), the present invention operates. If the phone is received after the vibration mode is set or the vibration data generator 211b or the like is received and needs to be recognized by the user (S502), the surrounding noise or illuminance of the mobile communication terminal is measured to check whether the environment is different from the previous one. (S503). If the point of time when the vibration occurred and the surrounding environment did not change, the vibration is generated at the last vibration level. If the time when the vibration occurred immediately before the illumination or noise is changed, it generates a vibration suitable for the surrounding environment, or generates a vibration according to the vibration level value set by the user (S504).

The vibration generated by the vibration generating unit 100 measures how much physical vibration in the actual mobile communication terminal. That is, the initial vibration level is measured to generate initial vibration level data (S505). Thereafter, by comparing the standard vibration level data and the initial vibration level data prepared in advance to determine whether there is a difference in the vibration level (S506).

If the initial vibration level data and the standard vibration level data match, the vibration is maintained as it is, and if the initial vibration level data and the standard vibration level data are different, the vibration of the mobile communication terminal is adjusted to the standard vibration level (S507). Finally, when the user issues a vibration end command to terminate the vibration (S508).

The embodiments and drawings attached to this specification are merely to clearly show some of the technical ideas included in the present invention, and those skilled in the art can easily infer within the scope of the technical ideas included in the specification and drawings of the present invention. Modifications that can be made and specific embodiments will be apparent that all fall within the scope of the present invention.

100: vibration generating unit 200: initial vibration level generating unit
210: initial vibration measurement unit 211: vibration measurement module
211a: Vibration measurement sensor 211b: Vibration data generator
212: noise measurement module 212a: microphone
212b: Ambient Noise Filter 212c: Noise-Vibration Data Generator
213: video measurement module 213a: camera
213b: image-vibration data generator 220: initial vibration measurement unit
300: standard vibration level generating unit 400: vibration control unit
500: memory

Claims (22)

In the mobile communication terminal of which the vibration level is adjusted,
Vibration generating unit for generating a vibration, when the mobile communication terminal is set to the vibration mode;
An initial vibration level generator for generating initial vibration level data of the initial vibration level generated by the vibration generator;
A standard vibration level generator for generating standard vibration level data for the mobile communication terminal; And
If the standard vibration level data and the initial vibration level data is different, the vibration control unit for controlling the vibration generating unit to change the vibration level of the mobile communication terminal to the standard vibration level,
The initial vibration level generating unit is a mobile communication terminal for adjusting the vibration amount through the self-recognition, characterized in that it comprises an initial vibration amount measuring unit including any one or more of a vibration measuring unit, a noise measuring module or an image measuring module. delete The method of claim 1,
The initial vibration level generation unit controls the initial vibration amount to control at least one of the vibration amount measurement module, the noise measurement module, or the image measurement module according to an environmental factor including at least one of a noise factor, an illuminance factor, and an image change factor. A mobile communication terminal for adjusting the vibration amount through a self-recognition, characterized in that it further comprises a measurement control unit. The method of claim 1,
The initial vibration level generating unit is a mobile communication to adjust the amount of vibration through the self-recognition, characterized in that at least one of the vibration measuring module, the noise measuring module or the image measuring module operates in accordance with the input value or a predetermined value terminal. The method of claim 1,
The vibration amount measuring module adjusts the vibration amount through self-recognition, characterized in that when the vibration occurs in the vibration generating unit, by measuring the vibration amount of the mobile communication terminal itself to generate the initial vibration level data. The method of claim 1,
The noise measuring module generates initial vibration level data by measuring one or more of the amount of noise generated by the mobile communication terminal itself or the vibration noise ratio of the mobile communication terminal compared to the ambient noise when the vibration is generated in the vibration generating unit. Mobile communication terminal for adjusting the amount of vibration through self-recognition, characterized in that. The method of claim 1,
The image measuring module is a mobile communication terminal for adjusting the amount of vibration through the self-recognition, characterized in that when the vibration occurs in the vibration generating unit, by measuring the focus shake of the surrounding image due to the vibration to generate the initial vibration level data. The method of claim 1,
The standard vibration level data generated by the standard vibration level generator is a value input in advance or a value set according to the surrounding environment of the mobile communication terminal. The method of claim 1,
The vibration generating unit is a mobile communication terminal for adjusting the amount of vibration through self-recognition, characterized in that for generating a vibration at the previous vibration level. 10. The method of claim 9,
The vibration generating unit further includes an illumination sensor, and when the illumination intensity is not changed by comparing the current illuminance with the illuminance of the immediately preceding vibration point using the illuminance sensor, self-recognition, characterized in that to generate a vibration at the previous vibration level. Mobile communication terminal to adjust the amount of vibration through. 10. The method of claim 9,
The vibration generating unit further includes a noise sensor, and when the noise level is not changed by comparing the current amount of noise with the amount of noise at the previous vibration time using the noise sensor, generating a vibration at the previous vibration level. Mobile communication terminal for adjusting the amount of vibration through self-recognition. In the method for adjusting the vibration amount in the mobile communication terminal,
Step S1 of generating data on an initial vibration level, which is a vibration level at the time when vibration occurs in the mobile communication terminal;
Step S2 of generating standard vibration level data for the mobile communication terminal; And
If the standard vibration level data and the initial vibration level data generated in the step S2 is different from the vibration level of the mobile communication terminal includes a step S3,
Initial vibration level data generated in the step S1 is generated through the self-recognition in the mobile communication terminal, characterized in that it is generated through the initial vibration amount measurement unit including any one or more of the vibration measurement module, noise measurement module or image measurement module How to adjust the amount of vibration. delete The method of claim 12,
The initial vibration measuring unit is characterized in that any one or more of the vibration measuring module, noise measuring module or image measuring module operates according to an environmental factor including any one or more of the noise factor, illuminance factor or image change factor. How to adjust the amount of vibration through self-recognition in the mobile communication terminal. The method of claim 12,
The initial vibration amount measuring unit measures the vibration amount through the self-recognition in the mobile communication terminal, characterized in that at least one of the vibration amount measuring module, noise measuring module or image measuring module operates according to an input value or a predetermined value. How to adjust. The method of claim 12,
The vibration amount measuring module adjusts the amount of vibration through self-recognition in the mobile communication terminal, characterized in that for measuring the vibration energy of the mobile communication terminal itself, when the vibration occurs in step S1. The method of claim 12,
The noise measuring module, when the vibration occurs in step S1, the mobile communication terminal characterized in that for measuring one or more of the amount of noise generated in the mobile communication terminal itself due to the vibration or the noise ratio of the vibration of the mobile communication terminal compared to the ambient noise How to control the amount of vibration through self-recognition The method of claim 12,
The image measuring module adjusts the amount of vibration through self-recognition in the mobile communication terminal, if the vibration occurs in the step S1, the focus shake of the surrounding image due to the vibration. The method of claim 12,
The standard vibration level data generated in the step S2 is a value input in advance or a value set according to the surrounding environment of the mobile communication terminal. The method of claim 12,
The vibration of the mobile communication terminal generated in the step S1 is a method of controlling the amount of vibration through self-recognition in the mobile communication terminal, characterized in that the vibration of the previous vibration level is generated. The method of claim 20,
The step S1 is a method of adjusting the amount of vibration through the self-recognition in the mobile communication terminal, characterized in that the vibration of the previous vibration level is generated when there is no change in the illumination by comparing the current illumination and the illumination of the last vibration time. The method of claim 20,
In the step S1, when the noise level does not change by comparing the current noise level with the noise level at the last vibration time, the vibration is generated at the immediately previous vibration level through self-recognition in the mobile communication terminal. How to adjust the amount of vibration.

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