CN111709178A - Three-dimensional space-based acoustic particle drop point simulation analysis method - Google Patents

Abstract

The invention relates to the technical field of architectural acoustics, in particular to a three-dimensional space-based acoustic particle drop point simulation analysis method, which comprises the following steps of: picking up a sound source point A, a reflecting surface A and a seat surface B; step 2: uniformly taking points B on the reflecting surface A; and step 3: connecting the point B with the sound source point A to obtain a line segment A, and extending the line segment A to obtain a line segment B; and 4, step 4: taking the point B as a datum point, mirroring the line segment B by referring to the reflecting surface A, and mirroring to obtain a line segment C; and 5: moving the seat surface B upwards for a certain distance to obtain an actual audience surface C of the human ear; step 6: the line segment C is extended, and the intersection point of the extension line of the line segment C and the actual audience surface C is a point C; and 7: and drawing a circle by taking the point C as the center of the circle to obtain a circle A, wherein the circle A is the drop point of the actual sound particle.

Description

Three-dimensional space-based acoustic particle drop point simulation analysis method

Technical Field

The invention relates to the technical field of architectural acoustics, in particular to a three-dimensional space-based acoustic particle drop point simulation analysis method.

Background

Building acoustics is the science of studying the acoustical environmental problem in the building, including the sound propagation in the building environment, the evaluation and control of sound, is the component of building physics, is used for controlling indoor tone quality and the noise of building environment to guarantee that indoor has good listening and listening conditions. At present, in the prior art, a planar two-dimensional method is adopted to perform simulation analysis on a sound reflection drop point in a building environment, the drop point of a sound particle cannot be intuitively simulated and predicted by means of hand-drawing analysis or CAD analysis, so that limitation and errors existing in a simulation process are large, and the method is inconvenient to use. In view of this, we propose a three-dimensional space-based acoustic particle landing point simulation analysis method.

Disclosure of Invention

The invention aims to provide a three-dimensional space-based acoustic particle landing point simulation analysis method to solve the problems in the background art.

In order to achieve the purpose, the invention provides the following technical scheme:

a method for simulating and analyzing the falling point of an acoustic particle based on a three-dimensional space comprises the following steps:

step 1: picking up a sound source point A, a reflecting surface A and a seat surface B;

step 2: uniformly taking points B on the reflecting surface A;

and step 3: connecting the point B with the sound source point A to obtain a line segment A, and extending the line segment A to obtain a line segment B;

and 4, step 4: taking the point B as a datum point, and mirroring the line segment B by referring to the reflecting surface A to obtain a line segment C;

and 5: moving the seat surface B upwards for a certain distance to obtain an actual audience surface C of human ears;

step 6: the line segment C is extended, and the intersection point of the extension line of the line segment C and the actual audience surface C is a point C;

and 7: and drawing a circle by taking the point C as the center of the circle to obtain a circle A, wherein the circle A is the drop point of the actual sound particle.

Preferably, in step 2, the ratio of the number of dots of the dots B to the area of the reflecting surface a is not less than 100 dots per square.

Preferably, in step 5, the distance of the seat surface B moving upwards is not less than 70 cm.

Preferably, the sound source point a and the circle a are colored, and the color of the circle a corresponding to the sound source point a is consistent, so as to visually represent the falling point position of the sound source point a on the actual audience surface C.

Compared with the prior art, the invention has the beneficial effects that: the method comprises the steps of uniformly taking points B on a reflecting surface A, connecting the points B with a sound source point A to obtain a line segment A, extending the line segment A to obtain the line segment B, mirroring the line segment B to obtain a line segment C, drawing a circle by taking the point C as a circle center to obtain a point circle A of actual sound particles, determining the sound particle falling points at different positions of the whole sound source by picking up the plurality of points A, and representing the sound particle falling points through different color mirror images, so that the simulation analysis of the sound particle falling points in the three-dimensional space is completed, the error is small, and the use is convenient.

Drawings

FIG. 1 is a schematic diagram of the operation of the method of the present invention;

FIG. 2 is a flow chart of the method operations of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-2, a technical solution provided by the present invention is:

a three-dimensional space-based acoustic particle drop point simulation analysis method comprises the following steps:

step 1: picking up a sound source point A, a reflecting surface A and a seat surface B;

step 2: uniformly taking points B on the reflecting surface A;

and step 3: connecting the point B with the sound source point A to obtain a line segment A, and extending the line segment A to obtain a line segment B;

and 4, step 4: taking the point B as a datum point, mirroring the line segment B by referring to the reflecting surface A, and mirroring to obtain a line segment C;

and 5: moving the seat surface B upwards for a certain distance to obtain an actual audience surface C of the human ear;

step 6: the line segment C is extended, and the intersection point of the extension line of the line segment C and the actual audience surface C is a point C;

and 7: and drawing a circle by taking the point C as the center of the circle to obtain a circle A, wherein the circle A is the drop point of the actual sound particle.

In this embodiment, in step 2, the ratio of the number of the points B to the area of the reflecting surface a is not less than 100 points per square, the area of the reflecting surface a in this embodiment is 20 square meters, and the number of the points B is 2000, so that a plurality of points B can be uniformly captured to perform the analysis of the drop point, and the accuracy of the analysis result is improved.

Further, in step 5, the upward moving distance of the seat surface B is not less than 70cm, and the position of the human ear is higher than the height of the seat surface B, so that the position of the actual falling point of the sound particle obtained by the human ear can be obtained in the upward moving process of the seat surface B, so that the analysis result is more accurate, and the upward moving distance of the seat surface B in this embodiment is 1 m.

It should be noted that the sound source point a and the circle a are colored, and the color of the sound source point a is consistent with that of the circle a corresponding to the sound source point a, so as to visually represent the position of the sound source point a on the actual audience surface C, which is convenient for observation.

When the sound particle landing point simulation analysis method based on the three-dimensional space is used, the three-dimensional space where a sound source is located is simulated through rhinoceros software, and a sound source point A, a reflecting surface A and a seat surface B are picked up in the three-dimensional space according to actual operation requirements; uniformly taking a point B on a reflecting surface A, connecting the point B with a sound source point A to obtain a line segment A, extending the line segment A to obtain a line segment B, taking the point B as a reference point, mirroring the line segment B by referring to the reflecting surface A, obtaining a line segment C after mirroring, moving the seat surface B by a distance to obtain an actual audience surface C of human ears, extending the line segment C, drawing a circle by taking the point C as the center of the circle, wherein the intersection point of the extension line of the line segment C and the actual audience surface C is taken as the point C, obtaining a circle A, the circle A is the falling point of actual sound particles, coloring the sound source point A and the circle A, the colors of the circle A corresponding to the sound source point A are consistent, the falling point positions of the sound source point A on the actual audience surface C are visually represented, the falling points of the sound particles at different positions of the whole sound source are determined by picking up a plurality of points A and are represented by different color mirroring, therefore, the simulation analysis of the acoustic particle falling point in the three-dimensional space is completed, the error is small, and the popularization and the promotion are facilitated.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the preferred embodiments of the present invention are described in the above embodiments and the description, and are not intended to limit the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (4)

1. A three-dimensional space-based acoustic particle drop point simulation analysis method is characterized by comprising the following steps: the method comprises the following steps:

step 1: picking up a sound source point A, a reflecting surface A and a seat surface B;

step 2: uniformly taking points B on the reflecting surface A;

and step 3: connecting the point B with the sound source point A to obtain a line segment A, and extending the line segment A to obtain a line segment B;

and 4, step 4: taking the point B as a datum point, and mirroring the line segment B by referring to the reflecting surface A to obtain a line segment C;

and 5: moving the seat surface B upwards for a certain distance to obtain an actual audience surface C of human ears;

step 6: the line segment C is extended, and the intersection point of the extension line of the line segment C and the actual audience surface C is a point C;

and 7: and drawing a circle by taking the point C as the center of the circle to obtain a circle A, wherein the circle A is the drop point of the actual sound particle.

2. The method for the simulation analysis of the landing points of the acoustic particles based on the three-dimensional space according to claim 1, wherein: in step 2, the ratio of the number of the points B to the area of the reflecting surface A is not less than 100 points per square.

3. The method for the simulation analysis of the landing points of the acoustic particles based on the three-dimensional space according to claim 1, wherein: in the step 5, the upward moving distance of the seat surface B is not less than 70 cm.

4. The method for the simulation analysis of the landing points of the acoustic particles based on the three-dimensional space according to claim 1, wherein: and coloring the sound source point A and the circle A, wherein the color of the circle A corresponding to the sound source point A is consistent, and the circle A is used for visually representing the falling point position of the sound source point A on the actual audience surface C.

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