JP2009037143A - Auxiliary appliance for measurement - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an auxiliary appliance for measurement capable of exactly measuring a speaker installation position while suppressing a cost. <P>SOLUTION: A case 10 comprises an arm 21, an arm 22, and an arm 23 extending respectively toward an outer side with a spacing of 120° each from a central position. A groove 11, a groove 12, and a groove 13 on which microphones can be placed are provided to the front ends of the respective arms. Also, an indicator 14 comprising an arrow and characters are installed on the arm 21, and it acts as a measure when a user determines the direction in which the auxiliary appliance 1 for measurement is directed. An angle and a distance between a listening position and a speaker can be acquired by installing the auxiliary appliance 1 for measurement in a listening position, picking up the voices output from the speaker in each groove, and measuring the distance from the speaker. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an auxiliary instrument for measurement used when measuring the installation position of a speaker such as a home theater.

  Conventionally, in an environment where a plurality of speakers are installed, such as a home theater, the sound field of the installation environment is measured. By measuring the sound field in the installation environment and controlling the level of the audio signal supplied to each speaker based on the measurement result, a better sound field environment can be realized.

As a method for measuring the sound field of the installation environment, for example, a proximity four-point method as shown in Non-Patent Document 1 can be considered. In Non-Patent Document 1, four microphones are installed close to each other and impulse responses are recorded to measure the arrival direction and acoustic characteristics of reflected sound.
"Acoustic measurement of concert halls by the proximity four-point method", Yoshio Yamazaki, Satoshi Ito, JAS Journal No.10-1987

  However, according to the measurement method of Non-Patent Document 1, four microphones are required, and there is a problem that costs are increased.

  On the other hand, the distance between the listening position and each speaker can be measured with only one microphone, but detailed measurement such as the angle between the listening position and the speaker has not been possible.

  Accordingly, an object of the present invention is to provide an auxiliary instrument for measurement that can accurately measure a speaker installation position while suppressing cost.

  The measurement auxiliary instrument according to the present invention is a measurement auxiliary instrument having a housing having at least three microphone installation locations, and is provided with a sequence indicator that displays the order of microphone installation at each microphone installation location. A direction indicator indicating an installation direction at the time of measurement is provided at any location of the casing.

  In this configuration, three or more places where microphones are installed are provided in the housing of the auxiliary instrument for measurement. The order of installing microphones is displayed at each microphone installation location. For example, the number 1, number 2, and number 3 are displayed. Moreover, the indicator of the direction which faces a housing | casing is provided. The direction indicator may be composed of an arrow or a character. If one microphone is installed in order at three microphone installation positions and the distance to the speaker is measured, detailed measurements such as the angle between the listening position and the speaker can be performed. That is, if a measuring instrument (such as an audio amplifier) has information indicating the distance relationship between three microphone installation positions, the speaker installation position can be obtained by three-point surveying. Thereby, even if there is one microphone, the speaker installation position can be accurately measured by a simple operation in which the user places the microphones in order.

  Furthermore, the present invention is further characterized in that the microphone installation location is formed in a concave shape so as to follow the shape of the microphone.

  In this configuration, the microphone installation location is formed in a concave shape so as to follow the shape of the microphone. For example, if the microphone has a circular bottom plate, it may have a round groove shape.

  In addition, the present invention further includes four or more microphone installation locations, and a plurality of planes formed by connecting arbitrarily selected three microphone installation locations form different planes in space. The installation position is determined.

  In this configuration, four or more microphone installation locations are provided. There are a plurality of planes formed by connecting three microphone installation positions, and these planes form different planes. For example, four microphone installation locations are provided, and a geometric shape formed by connecting the microphone installation locations forms a regular tetrahedron. Thereby, if the measurement is performed at each microphone installation location, the installation location of the speaker can be obtained three-dimensionally.

  Further, the present invention is characterized in that the casing has a flat plate shape, the microphone installation place is provided on the upper surface side of the flat plate, and a screw hole is formed on the lower surface side of the flat plate.

  In this configuration, a screw hole is formed in the lower surface of the flat housing. This screw hole is, for example, an international standard tripod screw hole. The user can freely change the installation height of the auxiliary instrument for measurement by attaching a tripod to the screw hole.

  According to the present invention, even if there is only one microphone, the speaker installation position can be accurately measured while suppressing costs by performing measurement in order at each microphone installation position.

  An auxiliary instrument for measurement according to an embodiment of the present invention and a method for measuring a sound field environment using the auxiliary instrument for measurement will be described. In the present embodiment, when the user installs a microphone at the listening position, the audio device measures the positional relationship between the listening position and the speaker, and performs sound field correction based on the measured positional relationship. The auxiliary instrument for measurement serves as a jig for fixing and installing the microphone during the measurement.

  FIG. 1 is a top view showing an appearance of a measurement auxiliary instrument 1 according to the present embodiment, and FIG. 2 is a bottom view. FIG. 3 is a side view of the auxiliary instrument 1 for measurement.

  The measurement auxiliary instrument 1 includes a resin-integrated case 10, and the case 10 includes an arm 21, an arm 22, and an arm 23 that extend outward from the center position at intervals of 120 degrees. Each of the arm 21, the arm 22, and the arm 23 has a thin flat plate shape with a height of about several millimeters to several centimeters, and the tip is rounded in an arc shape. The length of each arm is about several tens of centimeters, and all have the same length. Connecting the vertices of these arms forms an equilateral triangle.

  The arm 21, the arm 22, and the arm 23 have a groove 11, a groove 12, and a groove 13 formed at their tips, respectively. The groove 11, the groove 12, and the groove 13 each have a circular shape when viewed from the upper surface of the housing, and the depth of the groove is about several mm. The tip of each arm is rounded in an arc shape along the circular shape of these grooves.

  As viewed from the top surface of the housing, numerals are formed on the inner surfaces of the groove 11, the groove 12, and the groove 13. In this embodiment, the number 1 is formed in the groove 11, the number 2 is formed in the groove 12, and the number 3 is formed in the groove 13. An indicator 14 is formed on the upper surface of the arm 21. The indicator 14 is composed of an arrow and a character (FRONT DIRECTION), and serves as a guide when the user determines the direction in which the measurement auxiliary instrument 1 is directed at the time of measurement. The indicator 14 is not limited to an arrow or a character, but may be any indicator as long as it serves as a guide for the direction.

  A screw hole 35 is formed on the lower surface of the housing 10. The screw hole 35 is an international standard tripod screw hole. The user can freely change the installation height of the auxiliary instrument for measurement by attaching a tripod to the screw hole 35.

  When measuring the positional relationship between the listening position and the speaker, the user places the measurement auxiliary instrument 1 at the height of the listening position, and places the measurement microphone in the order of the groove 11, the groove 12, and the groove 13. By measuring the distance between the microphone and the speaker at the position of each groove, the installation position of the speaker can be measured.

  FIG. 4 is a diagram showing an example of use of the measurement auxiliary instrument 1 when measuring the positional relationship between the listening position and the speaker. The audio device 71 is connected to the microphone 51, the speaker 91R, and the speaker 91L. The audio device 71 is a so-called AV amplifier, which corrects an audio signal input from a playback device such as a DVD player (not shown) and outputs the corrected audio signal to the speaker 91R and the speaker 91L. Also, the audio device 71 inputs an audio signal picked up by the microphone 51.

  The audio device 71 controls the delay amount and level of the audio signal supplied to each speaker, for example, based on the positional relationship between the listening position and each speaker, and corrects to a better sound field environment.

  In the figure, the user installs the auxiliary measuring instrument 1 at the listening position. The listening position is ideally the position of the user's head. At this time, using the direction indicated by the indicator 14 as a guide, the user directs the groove 11 of the auxiliary measuring instrument 1 in the front direction (the direction in which the user faces when listening to sound). Further, the user installs the microphone 51 in the groove 11 of the auxiliary measuring instrument 1. Since the inner diameters of the groove 11, the groove 12, and the groove 13 are set to be substantially the same as the outer diameter of the bottom surface of the microphone 51, the user can easily fix and install the microphone 51 only by placing it in each groove. The user instructs the audio device 71 to measure the sound field environment after installing the microphone 51 in the measurement auxiliary instrument 1. Note that the user gives an instruction for measurement from a remote controller provided on the audio device 71 or a front operation panel.

  When the user instructs measurement, the audio device 71 outputs a measurement signal from one of the speakers (for example, the speaker 91L). The measurement signal may be any signal, but may be, for example, a chirp or a swept sign.

  When the measurement signal reaches the microphone 51, the audio device 71 inputs the sound signal picked up by the microphone, and measures the time difference between the sound output timing of the speaker 91L and the sound input timing of the microphone 51. Thereby, the distance from the speaker 91L to the position of the groove 11 where the microphone 51 is installed can be measured.

  Next, the user moves the microphone 51 from the groove 11 to the groove 12. At this time, a display (or voice guidance) that prompts the audio device 71 to move the microphone 51 to the groove 12 may be performed. Thereafter, a measurement signal is output from the speaker 91L in the same manner as described above, and the distance between the speaker 91L and the position of the groove 12 is measured. The timing for outputting the measurement signal may be determined by the user, or may be automatically output by the audio device 71 after a predetermined time has elapsed.

  Further, the user moves the microphone 51 from the groove 12 to the groove 13, and the audio device 71 outputs a measurement signal, and measures the distance between the speaker 91 </ b> L and the position of the groove 13.

  As described above, the audio device 71 measures the distance between the speaker 91L and the position of each groove. Since the distance between the speaker 91L and the position of each groove can be obtained, the position (planar coordinates) of the speaker 91L in the installation environment can be obtained if the audio device 71 has information on the positional relationship between the grooves. it can. The position of the speaker 91L can be obtained by two-dimensional coordinates with the listening position as the origin, or can be obtained by a distance and an angle from the listening position. Similarly, the position of the speaker 91R in the installation environment can be obtained. Thereby, the opening angle of the speaker 91L and the speaker 91R from the listening position can be obtained.

  The audio device 71 can perform various signal processing by obtaining the distance and angle from the listening position of each speaker. For example, the virtual sound source can be set by performing delay control or level control and changing the frequency characteristics of the audio signal. Further, it is possible to detect an error in the installation positions of the speaker 91L and the speaker 91R (such as being installed upside down), and to display that fact (or to provide voice guidance).

  4 shows an example in which the positional relationship between the speakers 91L and 91R is determined with respect to the listening position. Of course, in the case where a larger number of speakers such as rear speakers are installed, the positional relationship with each speaker is also shown. Can be sought.

  As described above, by using the measurement auxiliary instrument of this embodiment, even if there is one microphone, the distance to the speaker can be measured at three positions where the positional relationship is defined, and the cost can be reduced. Detailed sound field environment measurement can be performed accurately while suppressing.

  Next, FIG. 5 is a top view of the measurement auxiliary instrument 2 in another embodiment. In the measurement auxiliary instrument 2 shown in the figure, the same reference numerals are given to the same components as those in the measurement auxiliary instrument 1, and the description thereof is omitted.

  In the auxiliary measuring instrument 2 shown in the figure, an angle indicator 25 is installed at the center position of the housing 10. The angle indicator 25 is provided with a step at a predetermined angle (for example, every 1 degree) on the left and right, with the direction indicated by the indicator 14 being 0 degrees. The user can estimate the angle from the listening position to the installation position of each speaker with reference to the angle indicator 25. The audio device 71 can also perform various signal processing (delay control and level control) by inputting the estimated angle to the audio device 71.

  FIG. 6 is a top view and a perspective view of the auxiliary measuring instrument 3 in still another embodiment. FIG. 2A is a top view, and FIG. 2B is a perspective view. In addition, also in the measurement auxiliary instrument 3 shown in the figure, the same reference numerals are given to the same components as those of the measurement auxiliary instrument 1, and the description thereof is omitted.

  The auxiliary measuring instrument 3 shown in FIGS. (A) and (B) is provided with a column 32 and a dish 31 at the center position of the housing 10. The column 32 extends from the center of the housing 10 in the upper surface direction (vertically upward if the measurement auxiliary instrument 3 is installed horizontally), and the dish 31 is connected to the upper surface side end of the column 32. As with the grooves 11, 12, and 13, the dish 31 has a circular shape when viewed from the top, has a depth of about several millimeters, and has an inner diameter that is substantially the same as the bottom outer diameter of the microphone 51. Have. Therefore, the user can easily fix and install the microphone 51.

  A tetrahedron is formed when the apex of each arm of the auxiliary instrument 3 for measurement and the upper end (dish 31) of the column 32 are connected. As illustrated in FIG. 4, when measuring the positional relationship between the listening position and the speaker using the measurement auxiliary instrument 3, the user installs the microphone 51 on the plate 31 after the measurement at the position of the groove 13. Then, the audio device 71 outputs a measurement signal from the speaker 91L (speaker 91R) and measures the distance from the microphone 51.

  Thereby, the audio device 71 measures the distance between each speaker and each groove and the position of the dish 31. Since the distance between the speaker and each groove and the position of the dish 31 can be obtained, if the audio device 71 has information on the positional relationship between the groove and the dish 31, the three-dimensional coordinates of the speaker in the installation environment can be obtained. Can be sought. Thereby, the spatial positional relationship between the speaker 91L and the speaker 91R from the listening position can be obtained, and more various sound field corrections can be performed.

  In the present embodiment, an example in which a microphone is installed in each groove has been described. However, the microphone may be locked in each groove. For example, a notch or the like may be provided in the groove, and the microphone housing may be engaged with the notch. The positional relationship can be measured more accurately by locking the microphone in each groove.

  In addition, the measurement auxiliary instrument shown in this embodiment does not limit the dimension of the measurement auxiliary instrument in the present invention. By increasing the length of each arm and increasing the distance between the grooves, it is possible to perform measurement with higher accuracy. However, when the arm is lengthened, the size of the auxiliary instrument for measurement increases, making it difficult to handle. Therefore, what is necessary is just to set the dimension of the auxiliary instrument for a measurement suitably according to a use condition and cost. In addition, the shape of the housing is not limited to the shape shown in the above embodiment as long as at least three microphone installation locations can be provided.

It is a top view of the auxiliary instrument 1 for measurement. It is a bottom view of auxiliary instrument 1 for measurement. It is a side view of the auxiliary instrument 1 for a measurement. When measuring the relationship between a speaker and a listening position, it is the figure which showed the usage example of the auxiliary instrument 1 for a measurement. It is a top view of the auxiliary instrument for a measurement in another embodiment. It is the upper side figure and perspective view of the auxiliary instrument for a measurement in another embodiment.

Explanation of symbols

1-Auxiliary instrument for measurement 10-Housing 11, 12, 13-Groove 14-Indicators 21, 22, 23-Arm

Claims (4)

An auxiliary instrument for measurement having a housing with at least three microphone installation locations,
At each microphone installation location, a sequence indicator that displays the order of microphone installation is provided.
An auxiliary instrument for measurement, characterized in that a direction indicator indicating an installation direction at the time of measurement is provided at any location of the casing.   The auxiliary instrument for measurement according to claim 1, wherein the microphone installation location is formed in a concave shape so as to follow the shape of the microphone. Provided with four or more microphone installation locations,
The microphone installation position is defined such that a plurality of planes formed by connecting three arbitrarily selected microphone installation positions form different planes in space, respectively. Item 3. An auxiliary instrument for measurement according to Item 2.   The said housing | casing is flat plate shape, provided the said microphone installation location in the upper surface side of the flat plate, and formed the screw hole in the lower surface side of the flat plate, The Claim 1, 2 or 3 characterized by the above-mentioned. The measuring aid described.

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