JP2008004023A - Environmental information output control system and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system for creating a space for improving creativity such that working efficiency or inspiration is enhanced while providing a relaxation effect by controlling a luminaire, speaker or blower set in an office space or the like to give an atmosphere of a remote place with various sensuous effects. <P>SOLUTION: This system comprises a remote place facility 10 set in a remote plate and including at least one environmental information collection device 12 for collecting at least one piece of environmental information of the remote place; an environmental information content server 20 for extracting characteristic component data of the collected environmental information; and a space facility 30 including at least out output device for outputting at least one piece of environmental information to a predetermined space according to the extracted characteristic component data. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an environment information output control technique for extracting features of various environments in a remote place as environment information and outputting them to a predetermined space facility.

  Until now, many reports are made about the relaxation effect which natural environment has (for example, refer nonpatent literature 1). In addition, CDs and DVDs that record sounds and images of streams, seas, and forests are also on sale. In addition, home appliances aimed at contributing to relaxation, such as negative ion emitters, are on the market.

On the other hand, various technologies related to “virtual reality (VR)” and “virtual environment” for constructing an environment that does not actually exist on the spot have been proposed (for example, see Non-Patent Document 2). .
Virtual reality (VR) is primarily focused on “reproduction” of a particular environment. For this reason, the main stimulus is often visual information in many cases, and the presentation stimulus has a strong cognitive load. In addition, since the degree of dependence on visual perception is greater than that of actual experience, there are problems such as VR sickness, physical instability, and psychological anxiety (see Non-Patent Document 3, for example). For this reason, it is difficult to apply it to uses such as relaxation and refreshment, and it has hardly been used for designing a comfortable living space.

  In addition, although video images that include images of the natural environment are being recognized for relaxation, it is necessary to continue to watch the images in order to obtain the effects, so use in places where intellectual work is performed reduces concentration There is a problem that the work efficiency is lowered.

  Some recent home appliances are intended for relaxing and refreshing with the intention of acting on limited sensations such as skin sensation and olfaction, for example, with air-conditioning equipment. There is no equipment to do so, and the creation and provision of a comprehensive comfort space has not yet been achieved.

On the other hand, the stress of people working in offices in metropolitan areas is isolated from the external environment as well as interpersonal factors, and it also keeps feeling of blockage surrounded by artifacts such as office equipment for a long time. It is suggested that it is caused.
Under such circumstances, it does not rely on visual stimuli with a strong cognitive load, mainly video, but it acts on other various senses in a comprehensive manner and brings relaxation effects due to the atmosphere of the natural environment while enriching work efficiency and ideas. It is necessary to create a space that improves creativity. However, no system has been proposed to create a space that enhances creativity and enhances work efficiency and ideas, while acting in a comprehensive manner and providing relaxation effects in office spaces. .
"Experimental study on noise stress recovery effect of green space based on electroencephalogram, heart rate response and subjective evaluation" Journal of the Japanese Institute of Landscape Architecture, 65 (5), 2002 http://www.evl.uic.edu/pape/CAVE/ “Effect of physical support on psychological anxiety in subjects with an immersive virtual environment”, Report of the Japan Society for Educational Technology, 3 (1), 2003

  The present invention controls lighting fixtures, speakers, and blowers installed in office spaces, etc., and acts on various sensations to make you feel the atmosphere of a remote place, while providing a relaxation effect and enriching work efficiency and ideas The purpose is to provide a system for creating a space that enhances creativity.

  This system collects environmental information from remote locations using various sensors such as cameras, microphones, and anemometers, and controls the lighting fixtures, speakers, and fans installed in office spaces via the communication network to feel the atmosphere in remote locations. It is a system to let you. Here, in this system, for example, when the glitter of the wave is recorded with the camera, the intensity and rhythm of the glitter are extracted and displayed based on the rhythm rather than presenting it as a video stimulus with a strong cognitive load. The lighting and the blower in the space are controlled. Thereby, the natural environment of a remote place can be made to feel as the atmosphere of the whole space, without disturbing a user's work. Further, the stimulus form presented by the output device is also changed depending on the status of the output device provided in the office space or the like.

  An environmental information output control system according to an aspect of the present invention includes a remote facility equipped with at least one environmental information collection device that is installed in a remote location and collects at least one environmental information of the remote location, and the collected environment An environment information content server that extracts feature component data of information, and a space facility that includes at least one output device that outputs at least one environment information to a predetermined space according to the extracted feature component data. And In addition, this invention is materialized not only as an apparatus but as invention of a method.

  ADVANTAGE OF THE INVENTION According to this invention, the lighting fixture, the speaker, and the air blower which were installed in the office space etc. can be controlled, and it can feel the atmosphere of a remote place by acting on various senses. Thereby, work efficiency and creativity can be improved with a relaxation effect.

Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic diagram showing the overall configuration of an environmental information output control system according to an embodiment of the present invention.
As shown in FIG. 1, the environmental information output control system according to the present embodiment includes a remote facility 10, an environmental information content server 20, and a space facility 30. The remote facility 10, the environment information content server 20, and the space facility 30 are communicably connected via the network 40. The network 40 includes various types of networks 40 such as various types of public line networks, such as wired and wireless, private line networks, and LANs.

The remote area facility 10 is installed in a remote area (in this specification, simply referred to as “remote area”) such as a resort area or a tourist area, and functions as an input system to collect environmental information. The remote facility 10 includes at least one environmental information collection device 12 (12-1, 12-2, ..., 12-n), an environmental information collection control unit 14, an environmental information transmission unit 16, and a network interface. 18 and so on.
The environmental information collection device 12 is various sensors and measures actual environmental information in a remote place. The various sensors are all sensors such as a microphone, a camera, a thermometer, a hygrometer, an anemometer, a sunshine meter, and a soil moisture meter, that is, all devices capable of detecting environmental information.

The environmental information collection controller 14 controls the operation of the environmental information collection device 12. Specifically, it is as follows. The environmental information collection control unit 14 manages the environmental information collection device 12 installed in a remote place and controls its operation. Thereby, the environmental information collection device 12 collects environmental information under the control of the environmental information collection control unit 14. The environment information collection control unit 14 manages remote location information, the installation status of the environment information collection device 12 and detailed information of the environment information collection device 12, and details will be described later via the network interface 18. The environment information content server 20 is provided with the information (that is, the remote location profile). Table 1 shows an example of a remote site profile. Table 1 shows a remote site profile when the remote site is a coast.

In Table 1, “environmental information collection device” indicates the type of environmental information collection device. In this case, the five environments of the camera 1, the microphone 1, the microphone 2, the thermometer, and the wind direction anemometer are shown. It shows that an information collection device is installed.
“Direction (directivity)” indicates a direction in which environment information is collected. For example, the camera 1 indicates that the range in which an image is collected is determined by the angle θ and the angle φ, and the microphone 1 is directional. This indicates that the microphone has the characteristics. In addition, the microphone 2 indicates that the microphone does not have directivity. Note that the thermometer and the anemometer are blank because they are not basically directional.
“Position” indicates the location where the environmental information collection device is installed in coordinates. In addition, since it is impossible to determine the environment where the environment information collection device is installed from only the coordinates, for example, the “position” of the thermometer is described as a shade, a sunny place, etc. along with the coordinates. You can leave it. Further, a tree shade may be added to the “position” of the anemometer as in the thermometer.
“Data amount” indicates the amount of data output from the environmental information collection device per unit time.
In Table 1, since “target” is the coast as the environment, “camera surface” is set as the camera 1 and “shore” is set as the microphone 1, but if the environment is forest, the microphone is set. One target may be a tree (birds singing) or a forest (sounds of leaves of trees), and it is preferable that the target, the environmental information collecting device, or the installation location thereof be appropriately changed depending on the environment.

  The environment information transmission unit 16 inputs the environment information collected by the environment information collection device 12 and transmits the environment information to the environment information content server 20 via the network interface 18.

  The environmental information content server 20 manages at least one remote facility 10, and based on the environmental information collected by the remote facility 10, the details are generated in at least one space facility 30 to be described later at a remote location. Deliver natural phenomenon characteristic components. The environment information content server 20 includes an environment information collection device management unit 21, a phenomenon feature component extraction unit 22, a phenomenon feature component extraction rule database 23, a phenomenon feature component database 24, a phenomenon feature component data selection unit 25, a phenomenon, A feature component data distribution unit 26 and a network interface 27 are included.

  The environmental information collection device management unit 21 manages the remote facility 10 installed at a remote location via the network interface 27. Specifically, the environment information collection device management unit 21 receives the installed device information and the remote site profile information related to the location transmitted from the remote site facility 10, and based on the remote site profile information, the remote site facility 10 It manages additions and deletions, configuration changes of the environment information collection device 12 provided in the remote facility 10, and the like. The addition or deletion of the remote facility 10 may be managed by the environmental information content server 20, or some standard (for example, a standard when the environment changes or environmental information is not sufficient) is provided. In addition, it may be performed based on the standard.

The phenomenon feature component extraction unit 22 processes the environment information received from the remote environment information collection device 12 according to the phenomenon feature component extraction rule recorded in the phenomenon feature component extraction rule database 23 to generate phenomenon feature component data. . A plurality of phenomenon characteristic component data is usually generated from one natural phenomenon. For example, if phenomenon wave component is taken as an example of phenomenon feature component data, for example, brightness information assuming that the change in brightness is expressed as light as it is, and wind speed information assuming that the rhythm of glitter is expressed in the wind Can be generated. In other words, for example, if the phenomenon feature component extraction rule is “wave glitter”, a rule that at least two data of brightness information and wind speed information is generated as the phenomenon feature component data is registered. The generated phenomenon feature component data is stored in the phenomenon feature component database 24.
The phenomenon characteristic component data, which will be described in detail later, is data obtained by converting a temporal change component of a natural phenomenon occurring in a remote place into a physical quantity range suitable for a work space, and using various output devices in the space facility 30. This data is processed into a form that reduces the cognitive load so as not to disturb the user's work when outputting.

  The phenomenon feature component data selection unit 25 reads the phenomenon feature component data stored in the phenomenon feature component database 24 and selects the phenomenon feature component data to be distributed to the space facility 30. Based on the output device information input via the network interface 27, the phenomenon feature component data selection unit 25 specifically includes, for example, the presence or absence of an output device capable of outputting the phenomenon feature component data in the space facility 30, the space Based on the environment of the facility 30, the phenomenon feature component data to be distributed to the space facility 30 is selected.

  The phenomenon feature component data distribution unit 26 distributes the phenomenon feature component data selected by the phenomenon feature component data selection unit 25 to the space facility 30 via the network interface 27.

  The space facility 30 is a facility provided in an office, a general residence, or the like, and is provided in a space for relaxing and enjoying a remote atmosphere. The space facility 30 includes a stimulus output device 32 (32-1, 32-2,..., 32-n), a stimulus output control unit 34, and a network interface 36.

The stimulus output device 32 is various output devices and output devices, and includes, for example, an illumination device such as a color LED, a blower, an air conditioner, a speaker, a display, an aroma generator, a vibrator, and the like. In FIG. 1, the stimulation output devices 32 and the environmental information collection devices 12 are described as having the same number, but of course they may not be the same. The configuration can be appropriately selected and changed according to the installation location of the environmental information collection device and the situation of the space facilities.
The stimulus output control unit 34 controls the stimulus output device 32. In other words, the stimulus output control unit 34 manages the operation state of the stimulus output device 32, operates it by giving actual control parameters, selects the presence information / operation information of the device, and selects the phenomenon feature component data of the environment information content server 20 To the unit 25.

  Further, a user effect measurement unit (not shown) may be provided. The user effect measurement unit is connected to the stimulus output control unit 34 or the network interface 36, and includes a sensor for real-time feedback and an input device when the user experiences a space. Specifically, the user effect measurement unit includes various physiological measurement devices (pulse wave meter, electrocardiograph, electroencephalograph, electromyograph, sweat meter, near infrared monitor, etc.) and simple input devices (buttons, The data and output information are fed back to the environment information content server 20. Of these pieces of information, when a measurement result or a user's judgment is obtained that has an effect such as a relaxation effect on a user for a certain physical quantity, the phenomenon feature component data for the physical quantity is given priority. It is preferable to store them as rules in the phenomenon feature component extraction rule database 23 so that they are extracted. Thereby, it is possible to preferentially extract feature component data that is more effective for the user.

  A specific operation example of the environmental information output control system according to the embodiment of the present invention configured as described above will be described with two examples.

(Operation example 1)
A case where attention is paid to the sky will be described. The sky changes in color and brightness according to time from dawn to day, day, night. In this case, first, images are collected by a camera which is one of the environmental information collecting devices 12 installed in a remote place. This video is transmitted to the environment information content server 20 via the environment information transmission unit 16 and the network interface 18.

  The phenomenon feature component extraction unit 22 of the environment information content server 20 has an image analysis function, and calculates physical quantities related to colors such as hue, saturation, and brightness of the sky part included in the video. Next, when this physical quantity is expressed by an LED lighting device as an output device, correction is performed so that it feels almost the same as the color that humans feel when looking at the sky (this correction is referred to as “primary correction”). . This correction is performed because even if the physical quantity related to the color obtained by analyzing the video is expressed as it is in the LED lighting device, a deviation from the color in the actual landscape or video is often felt. As a simple correction method, there are the following methods. Several test subjects are prepared and corrected based on the physical quantity obtained by analyzing the video, and modeled as a correction formula (see, for example, the correction formula in Table 2). As shown in Table 2, in many cases, it is known that saturation and lightness should be corrected to values larger than the measured values.

  Further, instead of simply calculating and correcting the “physical quantity”, it may be determined whether or not the physical quantity is appropriate based on the characteristics of the “physical quantity”, and the optimal physical quantity is selected. In this case, after the phenomenon feature component extraction unit 22 corrects the feature amount, the phenomenon feature component data selection unit 25 may select an optimum physical quantity according to the state of the space facility 30. Specifically, in “wave glitter”, which will be described in detail later, for example, when there are two parts representing “wave glitter (that is, a time-varying component of wave glitter)” in an image, two parts Compare the magnitude of fluctuations. Since the portion with large fluctuation is easier to convey “wave glitter” than the portion with small fluctuation, the portion with large fluctuation is selected as a physical quantity for expressing “wave glitter”. When the fluctuation is too fast or too intense and the output speed of the stimulus output device 32 is not in time, that is, the fluctuation speed of the input physical quantity is 0.01 seconds, but the output speed of the stimulus output device 32 is 0. In such a case, the physical quantity is not selected. In this case, the phenomenon feature component data selection unit 25 may select the physical quantity to be output to the space facility 30 having the stimulus output device 32 that can output the physical quantity, or the fluctuation speed that can be output by the stimulus output device 32. For example, a “wave glitter” portion may be found and its physical quantity may be measured.

Next, since it is possible that the appropriate physical quantity varies depending on the work space (for example, office, factory, etc.), an appropriate work space range is set according to the work space, and the corrected physical quantity is appropriate for the work space. Determine if it is within range. If the corrected physical quantity does not fall within the appropriate work space range, further correction is performed (this correction is referred to as “secondary correction”). The above correction formulas, parameters included in the correction formulas, and work space appropriate ranges are set for each combination of environment information and output device, and the information is stored in the phenomenon feature component extraction rule database 23. Is preferred. In this operation example, the phenomenon feature component extraction rule database 23 includes at least the information shown in Table 2.

  In Table 2, as a natural phenomenon, changes in the sky color are collected by the camera of the environment information collection device 12. The stimulus output device 32 is a color LED. Here, the physical quantity includes a physical quantity to be measured and an expression physical quantity to be output by the output equipment. For the hue (H), saturation (S), and lightness (L) that are physical quantities to be measured, the output from the color LED is Corrections that make people feel the same as when observing the environment are performed using a correction formula (primary correction). Correction equations H ′ = H, S ′ = S * 1.3, and L ′ = L * 1.2 + 1 are correction equations for primary correction of hue, saturation, and lightness, respectively. At this time, if the result of the primary correction is within the appropriate working space range of the space facility 30, the value is distributed to the space facility 30 by the phenomenon feature component data distribution unit 26 as the phenomenon feature component data. When the result of the primary correction is out of the appropriate work space range of the space facility 30, the distribution is performed after performing the following secondary correction so that the value falls within the proper work space range.

  For example, a case where the measured brightness of the sky color is the minimum value 50 and the maximum value 200 is considered. In this case, it is assumed that the appropriate work space range is the minimum value 100 and the maximum value 150. At this time, the difference between the brightness values of the actually measured maximum value and the minimum value is 150, and the difference between the brightness values of the maximum value and the minimum value of the work space appropriate range is 50. Thereby, it is understood that the appropriate range of the work space and the actually measured scale ratio are 1: 3. Accordingly, after making the actual measurement minimum value 50 correspond to the appropriate range minimum value 100 and the maximum value 200 corresponding to the appropriate range maximum value 150, the value obtained by multiplying the change of the actual measurement value by 1/3 and the optimum range minimum value 100 are added. By using the obtained values as phenomenon characteristic component data, it is possible to perform secondary correction adapted to the appropriate range of the work space.

Here, since this operation example is a visual stimulus of sky color change, it is common to output phenomenon feature component data with a lighting device. However, it is also conceivable to use a stimulus output device that applies this visual stimulus to other senses. This is because when there is no appropriate lighting device in the space facility 30, or when the user desires to use normal lighting for lighting, and the sky color change is emphasized in comparison with other changes. In some cases, the same natural phenomenon change may be output in addition to the lighting device. In such a case, for example, as shown in Table 3, the output device is a blower or a speaker, and physical quantities such as brightness and saturation are set as physical quantities such as light speed and bird voice sound volume. The change may be output as a change in wind speed or sound volume of a bird's voice. An example of the correction formula in this case is shown in Table 3.

(Operation example 2)
As an operation example 2, a case where the glitter of the wave illuminated by the sun is transmitted will be described. Assume that the acquired image is as shown in FIG. In FIG.
A: A portion where the brightness changes strongly and the glittering is intense, such as whether the light is reflected or not in conjunction with the movement of the sea
B: The part where the reflection of light is strong and continues to shine white
C: The brightness does not change much because there is little reflection
There shall be. At this time, the portion that humans feel as the “brilliant” in which the light changes most rapidly is the portion A between the portion B that reflects light most and shines white and the portion C that has the least amount of reflection. Therefore, the phenomenon feature component extraction unit 22 scans the entire screen with a few pixel rectangle (portion D in FIG. 2) by the image analysis function. Then, an area where the brightness change is most remarkable is automatically set as a glitter extraction part (part A ′ in FIG. 2). Then, the lightness is subjected to the above-described primary correction and secondary correction. The data is distributed as phenomenon feature component data by the phenomenon feature component data distribution unit 26. Note that if the scanning is performed once every certain time such as at intervals of several minutes, it is possible to cope with the change of the sparkling place. This phenomenon characteristic component data can be expressed as light using a color LED as shown in Table 4.

  Also, for a similar image, instead of scanning a rectangle of several pixels, scan a thin horizontal rectangle corresponding to the screen width from bottom to top, and calculate the physical quantity of the rectangle with the most remarkable change in brightness and saturation. good. Thereby, it is also possible to extract the wave rushing rhythm.

  As shown in FIG. 3, the present invention is also applicable to a case of a tree leakage day that is inserted between the leaves of trees. For example, since the gap between the leaves is hidden by the leaves swaying in the wind, the portion where the change in brightness is most severe (portion E in FIG. 3) may be scanned and automatically detected. In addition, a portion that is likely to change drastically may be set in advance. Then, by correcting the physical quantity of the rectangular portion, it is possible to create phenomenon characteristic component data representing the rhythm of the sunbeams.

  By the way, as described in the prior art, in order to provide a comprehensive comfortable space that acts on the five senses, it is preferable to present stimuli in a variety of senses in combination. Here, in this embodiment, an example in which the atmosphere of the natural environment of Karuizawa Forest is presented visually, auditorily, and tactilely, and the verification result of the effect are shown.

  Natural phenomena of interest were green color, sunbeams, wind, wild bird voice, and tree shaking. Here, for the green color and the sunbeams, after calculating the physical quantity from the video collected by the video camera using the above method and correcting it, the wall lighting and floor lighting using color LEDs, and the spotlight Output. In addition, wind was measured by a wind direction wind speed sensor as a physical quantity, and after correction, the wind was output to a blower. The sound of wild birds and the shaking of the trees was recorded using a microphone, and the sound was output as it was.

The subject was allowed to enter a space equipped with the above lighting, speakers, and blower, and had a few minutes of experience. Meanwhile, we also conducted a creativity test to detect the degree of creativity. For this creativity test, an experiment was performed on the number of words (answers) associated with a given term (the number of responses) and the evaluation of a third party (creativity) on the originality of the word. . For comparison, the same experiment was performed in a space where Karuizawa's landscape video was streamed and in a space where only ordinary fluorescent lighting was used. FIG. 5 shows the results of an experiment with 21 subjects.
First, the number of responses was 3.90 and 3.91 per person for only ordinary lighting and only natural video, respectively. The output by the space of Karuizawa according to the present embodiment was 4.37. The originality was 4.11 points and 4.20 points for only ordinary lighting and only for natural video, but 4.62 points for the output by Karuizawa space according to this embodiment. It became. Thereby, according to this embodiment, it turns out that an effect higher than only normal illumination or only natural video is acquired.

  As described above, according to the present embodiment, it is possible to feel a natural (environmental) atmosphere in a remote place without disturbing the user's work like image stimulation, and to bring about a relaxed state and an improvement in creativity.

The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention at the stage of implementation.
In the above embodiment, the environment information output control system is exemplified by a system including the remote facility 10, the environment information content server 20, and the space facility 30. However, the present invention is not limited to this, and the above functions can be realized. Any configuration may be used. For example, as shown in FIG. 5, the remote area facility may include an environment information content server to be a remote area facility 50. In FIG. 5, the same parts as those in FIG.
In the above embodiment, the phenomenon feature component data selection unit 25 selects the phenomenon feature component data according to the stimulus output device 32 installed in the space facility 30, but the phenomenon feature component data selection unit 25 may be omitted. In this case, all the phenomenon feature component data may be transmitted to the space facility 30, and the stimulus output control unit 34 of the space facility 30 may suppress the output of the phenomenon feature component data that does not exist.
In the above embodiment, the space facility 30 has been described as an example of a facility provided in an office or a general residence. However, the present invention is not limited to this, and the facility capable of outputting data distributed from the environment information content server 20 Alternatively, any device may be used. For example, the image data may be displayed as a standby screen or background screen of a personal computer or a portable terminal.
Further, the above embodiments include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements.

  In addition, for example, even if some structural requirements are deleted from all the structural requirements shown in each embodiment, the problem described in the column of the problem to be solved by the invention can be solved, and the effect described in the effect of the invention Can be obtained as an invention.

It is the schematic which shows the whole structure of the environmental information output control system which concerns on one Embodiment of this invention. It is a figure which shows the example of extraction of the glitter of a wave in case the natural environment is the sea. It is a figure which shows the example which extracts the fluctuation | variation of a tree leak day. It is a figure which shows the result which confirmed the effect in this embodiment by the creativity test | inspection. It is a figure which shows the other structural example of the environment information output control system which concerns on this embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Remote place equipment 12 ... Environmental information collection apparatus 14 ... Environmental information collection control part 16 ... Environmental information transmission part 18 ... Network interface 20 ... Environmental information content server 21 ... Environmental information collection apparatus management part 22 ... Phenomenon feature component extraction part 23 ... Phenomenon feature component extraction rule database 24 ... Phenomenon feature component database 25 ... Phenomenon feature component data selection unit 26 ... Phenomenon feature component data distribution unit 27 ... Network interface 30 ... Spatial equipment 32 ... Stimulation output device 34 ... Stimulation output control unit 36 ... Network interface 40 ... Network

Claims (6)

A remote facility equipped with at least one environmental information collection device installed in a remote location and collecting at least one environmental information of the remote location;
An environmental information content server for extracting characteristic component data of the collected environmental information;
An environment information output control system comprising: a space facility including at least one output device that outputs at least one environment information to a predetermined space according to the extracted feature component data.   The environmental information output control system according to claim 1, wherein the environmental information content server extracts a feature component data from the management information for managing the environmental information collection device and the environmental information collected by the environmental information collection device. An environmental information output control system comprising: a phenomenon feature component extraction unit.   The environmental information output control system according to claim 2, wherein the phenomenon characteristic component extraction unit extracts, as collected characteristic information, characteristic component data of the environmental information, which is accompanied by a temporal change. Environmental information output control system.   4. The environmental information output control system according to claim 3, wherein the phenomenon feature component extraction unit scans image data, sets a portion that changes with time as a result of the scan as feature component data, and An environmental information output control system that outputs the characteristic component data according to a change.   5. The environmental information output control system according to claim 1, wherein the environmental information content server outputs at least one feature component data to be output to the space facility according to the at least one output device. 6. An environment information output control system, further comprising a selection unit for selecting. Collect at least one remote environment information,
Extract the characteristic component data of the collected environmental information,
An environment information output control method, comprising: outputting at least one environment information to a predetermined space in accordance with the extracted feature component data.

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