JP2950442B2 - Image display system for simulating external force response of structures - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system for displaying, as a moving image, a time-varying response of a structure to an external force applied to the structure when the force changes with time.

[0002]

2. Description of the Related Art Generally, simulation of the response of a structure to an external force that changes with time is applied to the structure when the external force changes over time, for example, when designing a housing of an article or a building (particularly, a high-rise building). The strength (with respect to the external force) required by the housing or building is set in consideration of the simulation result, and the shape, material, and the like of the structure are determined so as to clear the set strength. . As an example, a case of simulating a response of a skeleton of a high-rise building to an earthquake wave applied to the high-rise building will be described.In general, it occurs for each steel material used to construct the skeleton and for each contact point between the steel materials. Computer graphics that simulates the response of the high-rise building based on the simulation results, for example, using an engineering workstation (hereinafter abbreviated as EWS). (Hereinafter, abbreviated as CG), a graph of a waveform showing a variation of the response with the passage of time, and the like are performed.
The image of G is displayed on the display of the EWS, and the graph is plotted and output on paper from, for example, a plotter connected to the EWS.

Conventionally, necessary setting values such as virtual seismic waves assuming an earthquake of the desired scale are set, and the set values are substituted into a predetermined calculation formula for simulation to perform a simulation for each response. Based on the simulation result, a graph showing a change of the external force response at a predetermined location of the high-rise building in a time series is created and printed out, and the sway of the entire high-rise building, that is, the CG relating to the deformation response is generated. Generally, an image is displayed on a display or the like of the EWS. Further, if necessary, a graph showing the input seismic waves in time series is also provided in the E
The plotter is plotted and output on paper in the same manner as the graph showing the fluctuation of the external force response, which is created in the WS. When the same seismic wave is applied to a plurality of high-rise buildings having different structures, the deformation response (swaying) of each high-rise building is converted into a CG image and compared.
In general, G images are displayed on individual EWS displays, and the displayed images on each display are viewed in parallel.

[0004]

However, as described above, conventionally, the output of the graph from the EWS and the CG
Since the output of the image is performed separately for the plotter and the display, for example, a designer who is looking at the CG image may visually
When the image is recognized, when confirming the state of the input seismic wave or the state of the external force response at a predetermined point at that time, it is possible to infer the aging time from the start of the display of the CG image. Therefore, it is necessary to confirm the external force response and the state of the input seismic wave at the predetermined location by looking at the value indicated by the graph on the paper corresponding to the analogous time. Therefore, the deformation response of the high-rise building, the external force response and the state of the input seismic wave at a predetermined location of the high-rise building,
It takes time and effort to confirm the mutual timings in time, and there is a problem that those temporal changes cannot be instantaneously compared.

Conventionally, when comparing the deformation response of a plurality of high-rise buildings with different structures to a single seismic wave, the same number of displays as the number of high-rise buildings to be simulated are required, and the comparative visual recognition is troublesome. However, there is a problem that the apparatus cost is increased.

[0006] The present invention has been made in view of the above circumstances, and the state of an external force applied to a structure, which changes with time,
An external force response of the structure, which can simultaneously and instantly compare a desired state of the response state of the structure with time to the external force and a state of a deformation response of the structure due to the external force. It is an object to provide a simulation image display system. Also, the present invention
When the same external force is applied to each of a plurality of structures having different structures from each other, a structure capable of simultaneously and inexpensively comparing the deformation response states that change with time of each structure with respect to the external force can be inexpensively compared. It is an object of the present invention to provide an external force response simulation image display system.

[0007]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention seeks, by simulation, a time-varying response of a structure to a time-varying external force applied to the structure when the force is applied to the structure. A system that displays the simulation result as a moving image,
Simulation means for performing a simulation calculation based on a plurality of input parameters including at least one parameter changing with time, and generating a simulation result as a plurality of output parameters including at least one parameter changing with time;
Input means for inputting a plurality of parameters necessary for the simulation, including data of the external force, which is a parameter that changes with time, to the simulation means; and outputting the simulation result by the simulation means to the output of the simulation means. Image display means that can be displayed as a moving image based on the parameters, the image display means comprising: a deformation response of the structure to the external force; and at least one of the input parameters that changes with time. Means for simultaneously displaying, in a moving image, at least one of the output parameters that changes with time; and synchronism between the moving image related to the deformation response of the structure and the moving image related to the parameter. Including synchronization means and including Moving image of the output parameter to be displayed deformation response at the same time as the structure is characterized in that it comprises a correlation diagram showing the correlation between two of said output parameter relates to a predetermined portion of said structure.

Further, in the present invention, the moving image of the input parameter displayed simultaneously with the deformation response of the structure is a waveform of the seismic wave. Further, in the present invention, the moving image of the output parameter displayed at the same time as the deformation response of the structure includes at least a waveform of a stress generated in a predetermined portion of the structure. Further, according to the present invention, the moving image of the output parameter displayed simultaneously with the deformation response of the structure includes at least a waveform of a displacement generated in a predetermined portion of the structure.

In the present invention, the correlation diagram shows a correlation between a first stress and a second stress generated in a predetermined portion of the structure. Further, according to the present invention, the correlation diagram shows a correlation between a first displacement and a second displacement generated in a predetermined portion of the structure. Also, the present invention
The correlation diagram shows a correlation between stress and displacement generated in a predetermined portion of the structure.

Further, according to the present invention, the image display means includes:
A means for simultaneously displaying, in a moving image, a time-dependent deformation response of each structure to the external force when the time-varying external force is applied to each of the plurality of structures having different structures; and And a synchronizing means for ensuring the synchronization of moving images with respect to the deformation response of the structure. Further, in the present invention, the external force is a virtual seismic wave that imitates a vibration wave of an earthquake of a desired scale.

[0011]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an outline of the processing performed in the earthquake response simulation image display system for a high-rise building according to one embodiment of the present invention. Lines connecting the blocks indicate data transmission and reception between the processings. Is shown. In the earthquake response simulation image display system 30 for a high-rise building shown in FIG. 1, for example, as shown in FIG. 2, a high-rise building 10 having a skeleton composed of a plurality of members (columns, beams) 11, 12, 13,. On the other hand, when a virtual seismic wave that changes with time is added, the entire high-rise building 10 and the members 1
, 12, 13, ..., nodes 21, 22, ... between members
Then, a simulation process of a response for each layer is performed. Note that, for example, EWS is used as hardware, and the result of the simulation processing is displayed on a display of the EWS.

In FIG. 1, reference numeral 31 denotes a parameter input process. Here, the mass M, rigidity K, and damping constant C of the high-rise building 10, the time interval of the input seismic wave, the input time, and Input processing of parameters that do not change with time, such as designation of display content to be displayed, and parameters that change with time, such as the acceleration Z of the input seismic wave, are performed. In this embodiment, parameters relating to the input seismic wave, such as the time interval of the input seismic wave, the input time, the acceleration Z, the maximum acceleration, etc., specify the past representative earthquake pattern by the EWS operator. Operation is performed, the time interval for the pattern, the input time,
Parameters such as the acceleration Z are retrieved from the EWS database and input processing is performed.

In the simulation process 32, each of the nodes 21 and 22 of the high-rise building 10 with respect to the input seismic wave is
The simulation calculation processing of displacement X, displacement velocity X ₁ , and displacement acceleration X ₂ , which are parameters that change with time, is performed in 2,..., And more specifically, the input parameters are converted into a basic relational expression MX ₂ + CX _The displacement X, the displacement speed X ₁ , and the displacement acceleration X ₂ are calculated by substituting ₁ + KX = MZ. Note that the relational expression MX ₂ + C
X ₁ + KX = MZ is a general expression for calculating the displacement X, the displacement speed X ₁ , and the displacement acceleration X ₂ , and actually, the displacement X, the displacement speed X for each of the nodes 21, 22,. _1, and when calculating the displacement acceleration X ₂ is the left side of the equation, the high-rise building 10 Sadamari values by the structure or the like of the respective nodes 21, 22, ... multiplication factor is unique for each Is done. However, in this embodiment, for simplicity of explanation, the respective nodes 21, 22, ... each of the displacement, the displacement speed, and generally the displacement X of the displacement acceleration, displacement velocity X _1,
And and it is represented by the displacement acceleration X _2.

In the simulation result processing 33,
Wherein each node 21, 22 is calculated, ... each of the displacement X is a parameter that varies with time, the displacement speed X _1, and based on the displacement acceleration X _2, wherein each node 21, 22, ...
, The absolute displacement S (displacement acceleration X ₂ + the acceleration Z of the input seismic wave), the relative displacement T of each member 11, 12,... (Subtraction of the displacement X at the nodes at both ends of the member), and the stress F (Hook's law, stress F = Simulation processing of rigidity K × displacement X) is performed. Further, in the simulation result processing 33, the spatial position coordinates P of each of the nodes 21, 22,..., The layer shearing force Q at each level of the high-rise building 10, the interlayer displacement R, and the high-rise building 10 Is performed for the simulation of the falling moment N and the like.
The processing in the simulation result processing 33 is a parameter that changes with time.

In the response data extraction process 34, the simulation result in the simulation process 32 and the simulation result processing process 33 in the simulation result processing process 33 are specified based on the display contents to be displayed on the EWS display specified at the stage of the input process 31. Among the processing result and the input parameters input in the input processing 31, the extraction processing of parameters necessary for display is performed. In the present embodiment, in the response data extraction processing 34, at least a moving image that shows, as a waveform, a state in which the value of the acceleration Z of the input seismic wave changes with time, and a time when the input seismic wave is added are described. The parameters necessary for displaying the moving image indicating the deformation response on the appearance of the high-rise building 10 that changes together with the moving image are extracted.

In the binarization conversion process 35, parameters related to the spatial position coordinates P of the nodes 21, 22,... Among the processing results obtained in the simulation result processing process 33 and extracted in the response data extraction process 34. The process of converting the data of the text data into the state of binary data is performed so that the data with the parameters can be displayed as a CG image on the display of the EWS.

In the deformed response image creating process 36 ₁ , display is performed based on the parameters related to the spatial position coordinates P of the nodes 21, 22,... Among the parameters extracted in the response data extracting process 34. The coordinates of the nodes 21, 22,... On the screen are assigned, that is, mapped, and further, a CG for showing a deformation response on the appearance of the high-rise building 10 which changes with time in a moving image on the display. An image is created. The input parameter image generating processing 36 _2, of the parameters extracted are extracted by the response data extraction process 34, an input parameters entered processed in the input processing 31, a parameter input parameters vary with time In some cases, a CG image to be shown on the display as a moving image, and in other cases, a still image, is created.

Response image creation processing 36 ₃ , 36 ₄ ,..., 3
In 6 _n, on the basis of parameters extracted are extracted by the response data extraction process 34, each member 11, 1
, And the simulation results of the shearing force, bending moment, etc. at each of the nodes 21, 22,.
A CG image for generating a moving image on the display to show how the correlation between the two simulation results changes with time is processed.

[0019] In the display process 37, the deformation response image creating process _361, the input parameter image generating processing 36 _2, and the response image creating process _363, 36 _4, ..., a CG image created treated at 36 _n the A process for displaying on the display of the EWS is performed. When two or more display contents to be displayed on the display of the EWS are specified at the stage of the input processing 31, the display contents corresponding to the respective display contents are set.
The deformed response image creation processing 36 ₁ , the input parameter image creation processing 36 ₂ , and the response image creation processing 36 ₃ , 36
₄ ,..., 36 _n , each CG image is processed in time synchronization with each other to ensure their synchronism, and then these CG images are simultaneously displayed on the display. Is performed.

Next, the form of the CG image displayed on the display of the EWS by the above processing will be described based on display examples shown in FIGS. First, in the screen 50 of FIG. 3 for displaying simulation results regarding predetermined nodes 21, 22,... In the high-rise building 10, an area 51 is input to the high-rise building 10 by the input processing 31. Which is a table of input parameters such as the mass M, stiffness K, damping constant C, and the input seismic wave pattern, time interval, input time, and maximum acceleration.
The G image 91 is displayed. Incidentally, the CG image 91 is due CG image created processed by the input parameter image generating processing 36 _2.

The area 5 on the screen 50 shown in FIG.
2 shows, as shown in FIG. 6, a swaying of the high-rise building 10 and the members 11, 12, 13,... Constituting the high-rise building 10 when the seismic wave is applied to the high-rise building 10.
The G image 92 is displayed. The CG image 92 is a moving image by CG image created processed by the deformation response image creating process _361, the appearance of the high-rise building 10 displayed in the CG image 92, the input seismic time It changes according to the change accompanying. Also, on the CG image 92, marks 92a indicating the positions of the predetermined nodes 21, 22,... Are displayed.

Further, an area 53 on the screen 50,
In FIG. 54, as shown in FIG. 3, the horizontal axis is a time axis, and the vertical axes are predetermined nodes 21, 22,... Of the high-rise building 10, respectively.
CG images 93 and 94 are displayed as waveforms showing the manner in which the values of the displacement and the acceleration change with time as the value of the displacement and the value of the acceleration of the displacement. This CG image 9
3 and 94 are the response image creation processes 36 ₃ and 36, respectively.
₄ ,..., 36 _n are moving images based on CG images created and processed. When the CG images 93, 94 are displayed, predetermined nodes 21, 22,.
Points 93a, 93 indicating the displacement at
4a is displayed while moving in the time axis direction while leaving its trajectory.

On the other hand, in the area 55 on the screen 50, as shown in FIG. 3, the horizontal axis is the time axis, and the vertical axis is the value of the acceleration Z of the input seismic wave. A CG image 95 is displayed, which shows the appearance of the CG image. The CG image 95 is a moving image by CG image created processed by the input parameter image generating processing 36 _2, when displaying the CG image 95, 95a that indicates the value of the acceleration Z is the locus It moves on the time axis while being displayed. The CG image 92, which is simultaneously displayed as one screen 50 on the display,
93, 94, and 95 are displayed in a state where they are synchronized with each other in time and their synchronization is secured.

Next, in the screen 60 of FIG. 4 for displaying the simulation results relating to the predetermined members 11, 12, 13,... In the high-rise building 10, the regions 61, 6 are displayed.
2 and 65 include areas 51, 50 on the screen 50 in FIG.
Similarly to 52 and 55, the CG images 91 and 9 are respectively used.
2,95 is displayed. In this case, the CG image 9
2, marks (not shown) indicating the positions of the predetermined members 11, 12, 13,... Instead of the marks 92a.
Is displayed.

The areas 63 and 6 on the screen 60
4, as shown in FIG. 4, the horizontal axis is a time axis, and the vertical axes are predetermined members 11, 12, 1 of the high-rise building 10, respectively.
As the values of the displacement and the value of the shearing force in 3,..., CG images 96 and 97 showing waveforms in which the values of the displacement and the shearing force change with time are displayed. This CG image 9
6 and 97 are the response image creation processes 36 ₃ and 36, respectively.
₄ ,..., 36 _n are moving images based on CG images created and processed by any of the predetermined members 11, 12, 1, 1 of the high-rise building 10 when the CG images 96, 97 are displayed.
Points 96a, 9 indicating the values of the displacement and the shear force at 3,.
7a is displayed while moving in the time axis direction while leaving its trajectory. The CG images 92, 96, 97, 9 displayed simultaneously as one screen 60 on the display.
5 are displayed in a state where they are synchronized with each other in time and their synchronism is secured.

Subsequently, in the screen 70 of FIG. 5 for displaying the correlation and the like of a plurality of simulation results on the predetermined members 11, 12, 13,... Of the high-rise building 10, areas 71, 72, 75 are displayed. , Similarly to the areas 51, 52, and 55 on the screen 50 of FIG.
G images 91, 92, and 95 are displayed. In this case, the predetermined members 11, 1 are also displayed on the CG image 92.
Marks (not shown) indicating the positions of 2, 13,... Are displayed.

As shown in FIG. 5, in the area 73 on the screen 70, the horizontal axis is the predetermined members 11, 1
, And the vertical axis represents the value of the axial force at the predetermined member 11, 12, 13,.
A CG image 98 is displayed that shows how the correlation between the shearing force and the axial force changes with time. This CG image 9
8, the response image creation processing 36 ₃ , 36 ₄ ,.
_n is a moving image based on a CG image created and processed by any one of the above-described structures. When the CG image 98 is displayed, the shear force and the axial force of the predetermined members 11, 12, 13,. A point 98a indicating the value is displayed while moving within the coordinates while leaving its trajectory.

On the other hand, in an area 74 on the screen 70, as shown in FIG. 5, the horizontal axis represents the value of the layer shearing force at each level of the high-rise building 10, and the vertical axis represents the value of the high-rise building 10. As each floor, a CG image 99 is displayed which shows a state in which the peak value of the layer shear force in each of the + and-directions in each floor of the high-rise building 10 changes with time. This CG image 99 is stored in the response image creation process 3
6 _3, 36 _4, ..., a moving image by CG image created treated with either 36 _n, when displaying the CG image 99, + in each layer for each of the high-rise building 10, - relates both The bar graphs 99a, 99b,... Showing the peak values of the layer shear force are displayed while being peak-held in both the + and-directions.

One screen 70 is displayed on the display.
The CG images 92, 98, 9 displayed simultaneously as
9 and 95 are displayed in a state where they are synchronized with each other in time and their synchronism is secured. In addition, regions 56, 66, in the screens 50, 60, 70 shown in FIGS.
An operation screen A for designating display contents to be displayed on the screens 50, 60, 70, that is, for inputting some of the input parameters, is displayed at 76.

As described above, according to the earthquake response simulation image display system for a high-rise building of this embodiment, the absolute acceleration S at each of the nodes 21, 22,.
The relative displacement T of 1, 12, 13, ..., the high-rise building 10
A moving image showing a simulation result such as a layer shear force Q, an interlayer displacement R, and a falling moment N of the high-rise building 10 for each story, and a desired moving image among moving images showing a waveform of an input seismic wave. When a seismic wave is applied to the high-rise building 10, at the same time as a moving image showing a time-dependent appearance deformation of the high-rise building 10 with respect to the seismic wave,
The moving images can be displayed on the same screen in a state where the moving images are synchronized in time and their synchronism is secured.

For this reason, the deformation in appearance of the high-rise building 10 and the simulation results of the shear force or the like at the predetermined members 11, 12, 13,... Or the predetermined nodes 21, 22,. The state can be confirmed by matching the timings with each other, and the comparison of those states can be performed easily and instantly.

The layout and size of each of the CG images 91 to 99 on the display are not limited to the sizes shown in FIGS. 3 to 5.
It is also possible to designate images 91 to 99 and enlarge and display only the designated CG image. Further, the image showing the correlation as shown in the CG image 98 is not limited to the correlation between the shearing force and the axial force, but may be the correlation between two elements in the stress or the two elements in the displacement. , The correlation between one element in the stress and one element in the displacement, etc. may be displayed.

In this embodiment, a case has been described in which a plurality of simulation results, input parameters, and the like are simultaneously displayed when a seismic wave is applied to a single high-rise building. For example, as shown in FIG. The two CG images 130 and 140 showing the sway of the high-rise buildings 110 and 120 when the same seismic wave is applied to the two high-rise buildings 110 and 120 having different levels from each other are represented by the waveform of the input seismic wave. May be displayed at the same time as the CG image 95 or the operation screen A indicating the operation.

In this case, the two CG images 130, 1
40 are each moving image by CG image created processed by the deformation response image creating process _361, these two C
The G images 130 and 140 and the CG image 95 are processed by the display processing 37 so as to be synchronized in time with each other to ensure their synchronism, and then are displayed as one screen 150 on the display. Displayed at the same time.
Thereby, two high-rise buildings 11 having different structures from each other
When the input seismic wave is added to 0 and 120, the state of the time-varying shaking of each of the high-rise buildings 110 and 120 with respect to the input seismic wave can be confirmed at the same time. Will be able to do it.

In the above-described embodiment, the case where the response of the high-rise building 10 to the input seismic wave when a virtual seismic wave is applied to the high-rise building 10 has been described. The seismic wave may be replaced by virtual wind power, and the present invention is applicable as a device that simulates a response when various external forces are applied to various structures other than the high-rise building 10 and displays the result. is there.

[0036]

As described above, according to the present invention, when a time-varying external force is applied to a structure, a time-varying response of the structure to the external force is obtained by simulation, and the simulation result is used as a moving image. A display system, comprising: performing a simulation calculation based on a plurality of input parameters including at least one parameter that changes with time; and outputting a plurality of output parameters including at least one parameter that changes with time. Simulation means generated by the simulation means, input means for inputting a plurality of parameters necessary for the simulation including data of the external force which is a parameter which changes with time, and simulation by the simulation means. Image display means capable of displaying a result of the application as a moving image based on the output parameter of the simulation means, wherein the image display means comprises a deformation response of the structure to the external force, and the input parameter Means for simultaneously displaying, in a moving image, at least one time-varying parameter of the at least one of the output parameters and at least one of the output parameters varying with the time, and the moving image related to a deformation response of the structure. A synchronizing means for ensuring synchronization between an image and a moving image related to the parameter, wherein the moving image of the output parameter displayed at the same time as the deformation response of the structure includes two output units related to a predetermined portion of the structure. The configuration includes a correlation diagram showing the correlation between parameters. Therefore, the state of the external force that changes with time and is applied to the structure, the desired state of the response state of the structure with time to the external force, and the state of the deformation response of the structure due to the external force , Simultaneously and instantaneously. Further, when the same external force is applied to each of the plurality of structures having different structures, the deformation response of each structure with time to the external force can be easily and inexpensively compared.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating an outline of a process performed by an image display system for simulating an earthquake response of a high-rise building according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a frame of a high-rise building for which a simulation is performed by the earthquake response simulation image display system of FIG. 1;

FIG. 3 is an explanatory diagram showing an example of a display screen of a display based on the display processing of FIG. 1;

FIG. 4 is an explanatory diagram showing an example of a display screen of a display based on the display processing of FIG. 1;

FIG. 5 is an explanatory diagram illustrating an example of a display screen of a display based on the display processing of FIG. 1;

FIG. 6 is an explanatory diagram showing an example of a moving image showing a swing of a high-rise building among images displayed on the display screens of FIGS. 3 to 5;

FIG. 7 is an explanatory diagram showing an example of a display screen of a display based on the display processing of FIG. 1;

[Explanation of symbols]

10 High-rise building (structure) 31 Parameter input processing 32 Simulation processing 37 Display processing 50, 60, 70, 150 Screen 91, 92, 93, 94, 95, 96, 97, 98, 9
9 CG screen

──────────────────────────────────────────────────の Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) G06F 17/50 JICST file (JOIS)

Claims (9)

(57) [Claims] 1. A system which obtains, by simulation, a time-varying response of a structure to an external force applied to the structure when the external force changes with time, and displays the simulation result as a moving image. Simulation means for performing a simulation calculation based on a plurality of input parameters including at least one parameter changing with time and generating a simulation result as a plurality of output parameters including at least one parameter changing with time; An input unit for inputting a plurality of parameters necessary for the simulation including data of the external force, which is a parameter that changes with time, to the simulation unit; and a simulation result by the simulation unit. Image display means capable of displaying a moving image based on the output parameter of the simulation means, wherein the image display means changes with time of the input parameter and a deformation response of the structure to the external force.
At least one parameter to be output and the output parameter
And at least one parameter varies with time of the data, and means for simultaneously displaying the moving picture, synchronization to ensure the simultaneity of the moving image relating to the parameters and the moving picture of the deformation response of the structure Means, wherein the moving image of the output parameter displayed at the same time as the deformation response of the structure includes a correlation diagram showing a correlation between the two output parameters with respect to a predetermined portion of the structure. Display system for simulating external force response of a moving structure. 2. The external force response of a structure according to claim 1, wherein the moving image of the input parameter displayed simultaneously with the deformation response of the structure is a waveform of the external force that changes with time. Simulation image display system. 3. The structure according to claim 1, wherein the moving image of the output parameter displayed simultaneously with the deformation response of the structure includes at least a waveform of a stress generated in a predetermined portion of the structure. Display system for simulating external force response of a structure. 4. The moving image of the output parameter, which is displayed simultaneously with the deformation response of the structure, includes at least a waveform of a displacement generated in a predetermined portion of the structure. Display system for simulating external force response of a structure. 5. The correlation diagram according to claim 1, wherein the correlation diagram shows a correlation between a first stress and a second stress generated in a predetermined portion of the structure. 2. An external force response simulation image display system for a structure according to claim 1. 6. The correlation diagram according to claim 1, wherein the correlation diagram shows a correlation between a first displacement and a second displacement generated in a predetermined portion of the structure. 2. An external force response simulation image display system for a structure according to claim 1. 7. The structure according to claim 1, wherein the correlation diagram shows a correlation between stress and displacement generated in a predetermined portion of the structure. External force response simulation image display system. 8. The image display means according to claim 1, wherein when the time-varying external force is applied to each of the plurality of structures having different structures, the time-dependent deformation response of each structure with respect to the external force is a moving image. 8. The apparatus according to claim 1, further comprising: means for simultaneously displaying a plurality of structures; and synchronizing means for ensuring synchronization of moving images with respect to deformation responses of the plurality of structures. 9. Display system for simulating external force response of a structure. 9. The external force response simulation of a structural body according to claim 1, wherein the external force is a virtual seismic wave imitating a vibration wave of an earthquake of a desired scale. Image display system.