JP2021163254A - Information processing apparatus and information processing method - Google Patents

Abstract

To provide an information processing apparatus and an information processing method that can improve convenience of a user.SOLUTION: An information processing apparatus comprises: a reception unit; a generation unit; and a provision unit. The reception unit receives a drag operation of equipment desired by a user for three-dimensional space data indicating a space within a predetermined facility. The generation unit generates 3D model information, in which equipment information having information of equipment installed within the facility three-dimensionally modelled is set at a predetermined installation available location, for space data, according to the drag operation received by the reception unit. The provision unit provides the 3D model information generated by the generation unit to the user.SELECTED DRAWING: Figure 1

Description

Embodiments of the present invention relate to information processing devices and information processing methods.

Conventionally, for example, an apparatus for creating a 3D model of an object has been proposed based on shape data obtained by scanning the object with a 3D scanner.

Utility Model Registration No. 3195609

However, the prior art only models the appearance of an existing object in 3D. For this reason, when the space in the facility is modeled in 3D at the time of new construction or remodeling of the facility, for example, it is easy to predict the lighting mode of the lighting device and reproduce the lighting mode according to the user's request. Not really. Therefore, there is room for further improvement in terms of improving user convenience.

An object of the present invention to be solved is to provide an information processing apparatus and an information processing method capable of improving user convenience.

The information processing device according to the embodiment includes a reception unit, a generation unit, and a provision unit. In the reception unit, the reception unit accepts the selection and drag operation of the equipment desired by the user with respect to the three-dimensional spatial data indicating the space in the predetermined facility. In response to the drag operation received by the reception unit, the generation unit can install equipment information in which the information of the equipment to be installed in the facility is three-dimensionally modeled with respect to the spatial data. Generates the 3D model information set in. The providing unit provides the user with the 3D model information generated by the generating unit.

FIG. 1 is a diagram showing an outline of an information processing system according to an embodiment. FIG. 2 is a diagram showing an example of an image of 3D model information regarding the installation of the duct rail. FIG. 3 is a diagram showing an example of an image of 3D model information regarding the installation of a lighting device that can be installed on a duct rail. FIG. 4 is a block diagram showing a configuration example of the information processing system according to the embodiment. FIG. 5 is a functional block diagram showing a configuration example of the information processing device according to the embodiment. FIG. 6 is a diagram showing an example of spatial data information. FIG. 7 is a diagram showing an example of equipment information. FIG. 8 is a sequence diagram showing a flow of processing for providing 3D model information executed in the information processing system according to the embodiment.

The information processing device 1 according to the embodiment described below includes a reception unit 34, a generation unit 32, and a provision unit 33. The reception unit 34 accepts the selection and drag operation of equipment related to the facility environment desired by the user. The generation unit 32 three-dimensionally models the information of the equipment 51 installed in the facility B with respect to the three-dimensional spatial data indicating the space SP in the predetermined facility B in response to the drag operation received by the reception unit 34. Generates 3D model information in which the installed equipment information 42 is set. The providing unit 33 provides the user with the 3D model information generated by the generating unit 32.

In the information processing apparatus 1 according to the embodiment described below, the generation unit 32 sets the equipment information 52, which is a three-dimensional model of the information of the duct rail R which is the equipment, in the place where the equipment can be installed, with respect to the spatial data. Generate information.

In the information processing device 1 according to the embodiment described below, the generation unit 32 sets the facility information 52, which is a three-dimensional model of the information of the lighting device D, which is the facility, as the installation location of the duct rail R with respect to the spatial data. Generate the 3D model information.

In the information processing device 1 according to the embodiment described below, the generation unit 32 generates 3D model information in which the equipment information 42, which is a three-dimensional model of the lighting mode of the lighting device D, is set for the spatial data.

The information processing device 1 according to the embodiment described below further includes a change unit 35. The changing unit 35 changes the equipment information 52 set in the 3D model information provided by the providing unit 33 in response to the drag operation received by the receiving unit 34.

In the information processing apparatus 1 according to the embodiment described below, the generation unit 32 further sets the spatial data with the incidental equipment information obtained by three-dimensionally modeling the information of the incidental equipment installed together with the equipment 51. Generate model information.

In the information processing apparatus 1 according to the embodiment described below, the providing unit 33 determines the in-stock warehouse, the number of stocks, and the delivery date of the equipment 51 according to the equipment information 42 arranged in the spatial data based on the 3D model information. Provide information to the user.

In the information processing apparatus 1 according to the embodiment described below, the providing unit 33 provides the user with information on the equipment cost of the equipment 51 according to the equipment information 42 arranged in the spatial data based on the 3D model information.

The information processing device 1 according to the embodiment described below further includes an acquisition unit 31. The acquisition unit 31 acquires three-dimensional spatial data based on the data measured by the sensor 10 in the spatial SP in the predetermined facility B. The generation unit 32 generates 3D model information in which the equipment information 42, which is a three-dimensional model of the information of the equipment 51 installed in the facility B, is set for the spatial data acquired by the acquisition unit 31.

Hereinafter, the management system according to the embodiment will be described with reference to the drawings. In the embodiment, the same parts are designated by the same reference numerals, and duplicate description is omitted.

(Embodiment)
First, the outline of the information processing system S according to the embodiment will be described with reference to FIG. FIG. 1 is a diagram showing an outline of the information processing system S according to the embodiment. The information processing system S shown in FIG. 1 is, for example, a 3D model of a facility in which the space SP in a predetermined facility B is converted into three-dimensional data, and the space data of the space SP converted into three-dimensional data is also converted into three-dimensional data. It is a system that generates 3D model information in which is set. Further, the information processing system S realizes various services by providing the generated 3D model information to various external devices 100.

The predetermined facility B is a building in which the internal space SP is relatively large and uses a lighting device (lighting equipment) in the space SP. For example, a detached house, a condominium, an apartment, or the like. Office buildings such as companies, commercial facilities such as stores, accommodation facilities such as hotels, government agencies such as government offices, financial institutions such as banks, educational institutions such as schools, medical institutions such as hospitals, research institutions such as research institutes, factories Such as industrial plants. In addition, large commercial facilities (shopping center / outlet mall / underground shopping center), entertainment facilities (theme park / amusement park / amusement park / zoo / aquarium / pool / bath facility), cultural facilities (hall / theater / library / museum / museum) , Complex facilities, sports facilities, temples and shrines, distribution bases, service areas (SA) and parking areas (PA), railway stations, roadside stations, airports, ports (boarding areas), etc. Further, it may be a moving body having a space equivalent to that of a building such as a large vehicle, a ship, or an aircraft.

Further, the space SP is a section partitioned by a wall, a partition, a floor, a ceiling, or the like, and is, for example, a room in a building, a warehouse, a passage, or the like. The entrance, corridor, bath, toilet, garage, etc. may be included. Further, it may be a cabin of a vehicle, a ship, an aircraft, or the like. That is, the space SP is a place where a person stays, goes in and out, or passes through. The space SP may be a place where a person lives or works, or may be a place where articles used by the person are stored. The space SP may exist in the facility or in a remote place outside the facility. Further, as long as the lighting device can be installed, it may be outdoors as well as indoors. Further, in the facility B, the space SP may be one or a plurality.

Further, the above-mentioned equipment is various equipment installed in the space SP, for example, electric lamp / lighting equipment such as a lighting device, equipment related thereto, and the like. That is, the equipment referred to here is equipment that can be retrofitted to the space SP, for example, excluding the equipment originally provided in the space SP such as windows and stairs. Further, the equipment may be, for example, a communication network arranged in the facility B or the like.

Here, as shown in FIG. 1, the information processing system S includes an information processing device 1, a sensor 10, and various external devices 100. The detailed configuration of the information processing system S will be described later with reference to FIG.

In the information processing system S, first, data indicating the three-dimensional shape of the space SP is measured by the sensor 10 provided in the space SP in the facility B (step S1). For example, the sensor 10 is a 3D scanner, a camera, or the like, and is mounted on a lighting device such as a lighting device with a camera, embedded in the ceiling / wall / floor surface of a space SP, or a ceiling / wall / floor surface. It may be installed on the surface of the ceiling, or it may be installed at a position away from the ceiling / wall / floor surface using a jig. The sensor 10 may be carried by a field researcher and brought into the space SP in the facility B. Then, the sensor 10 transmits the measured data to the information processing device 1.

Subsequently, the information processing device 1 generates three-dimensional spatial data of the spatial SP based on the data measured by the sensor 10 (step S2). Specifically, the information processing device 1 generates spatial data in which data measured by sensors 10 provided in each of a plurality of spatial SPs in one facility B are combined. That is, one spatial data is generated for one facility B. It should be noted that the spatial data of each of the plurality of spatial SPs included in one facility B may be generated. Further, the information processing device 1 may acquire spatial data from another server device or the like that generates spatial data. That is, the information processing device 1 may generate and acquire spatial data by itself, or may acquire it from another server device.

Subsequently, the information processing apparatus 1 sets the equipment information obtained by modeling the information of the equipment installed in the facility B in three dimensions with respect to the acquired (generated) spatial data, and generates the 3D model information (step S3). .. The equipment information is, for example, information generated based on the equipment dimension information acquired from a catalog or the like and the appearance information acquired by a sensor or a measuring device, and is a three-dimensional model corresponding to the size of spatial data. Information. When the equipment is a lighting device, the equipment information includes information in which the lighting mode such as the irradiation range, the irradiation intensity (light intensity), and the color temperature is three-dimensionally modeled. That is, the equipment information includes information on the specifications (performance) of the lighting device which is the equipment installed in the facility B.

Subsequently, the information processing device 1 provides the generated 3D model information to various external devices 100. For example, the information processing device 1 provides 3D model information to the external device 100, and the user possessing the external device 100 can use the 3D model information for work support, 3D modeling, and augmented reality (AR). , Simulation, virtual reality (VR) and other services are realized.

For example, in the above-mentioned service, by using the 3D model information, it is possible to confirm the installation position (arrangement) of the equipment, the carry-in route, and the like without actually going to the space SP. Further, by using the 3D model information and setting a desired position on the spatial data as a virtual viewpoint, it is possible to simulate the optimum installation position of the lighting device while looking at the lighting device, which is a facility, from the back, for example. Details of this point will be described later.

As described above, the information processing device 1 according to the embodiment executes the information processing method to generate and provide the 3D model information, so that the user who owns the external device 100 can share the 3D model information. You can use various services. That is, according to the information processing method according to the embodiment, the convenience of the user can be improved.

Further, the information processing device 1 according to the embodiment displays the 3D model information on the display unit of the external device 100, and the equipment information that can be installed in the space SP from the user's external device 100 who browses the displayed 3D model information. The user's desired equipment information selection and drag operation (drag and drop) are accepted from the list, and the equipment information installed in the space SP is changed according to the accepted drag operation (step S4). The step S4 may be performed before the step S3. For example, the information processing device 1 receives in advance from the user's external device 100 the selection and drag operation of the equipment information desired by the user from the list of equipment information that can be installed in the space SP, and first 3D. When generating the model information, the equipment information installed in the space SP may be changed according to the received drag operation.

Here, the position where the equipment information can be installed in the space SP is determined in advance by the layout of the space SP, the arrangement of the power supply equipment, and the like. That is, the equipment information can be installed only at a predetermined position. Also, if you select and install a lighting device, only the lighting devices that can be additionally installed are left from the list. Further, the allowable installable capacity is displayed on the display unit of the external device 100, and the capacity changes each time a lighting fixture is selected. In addition, a support display is displayed when the user gets lost in the lighting equipment. For example, priority items are selected from items such as atmosphere, illuminance, and energy saving, and recommended lighting fixtures are shown according to the selected items to support lighting design.

In addition, the information processing device 1 according to the embodiment notifies that when a lighting fixture (such as a product of another company) that is not on the management list is retrofitted after that from the power consumption capacity of the camera or sensor. In addition, based on the usage status (brightness, lighting time) of the lighting equipment, regular notification of usage status, proposal of lighting design change, notification of renewal according to the usage status of the user, etc. are performed.

In this way, in the information processing apparatus 1 according to the embodiment, by confirming the change of the equipment information based on the 3D model information, the customer, the worker, or the like actually goes to the site to change and confirm the equipment. There is no need for it, or the adjustment result of the equipment installation position can be confirmed in advance by arranging by simulation. That is, according to the information processing device 1 according to the embodiment, the convenience of the user can be improved.

Next, an image of 3D model information will be described with reference to FIGS. 2 and 3. FIG. 2 is a diagram showing an example of an image of 3D model information regarding the installation of the duct rail R. FIG. 3 is a diagram showing an example of an image of 3D model information regarding the installation of the lighting device D that can be installed on the duct rail R.

As shown in FIGS. 2 and 3, the user selects the equipment information desired by the user from the list of equipment information that can be installed in the space SP, and performs a drag operation to the space data.

First, as shown in FIG. 2, the user can select the equipment information of the duct rail R desired by the user from the list of equipment information of the duct rail R which is the equipment 51 and install it in the spatial data. Perform a drag operation to the location AL (installation permission area).

Here, the installable place AL is a predetermined position in the spatial data. For example, the installation location AL is predetermined by the layout of the space SP, the arrangement of the power supply equipment, and the like. The equipment information of the duct rail R can be installed only in the predetermined installation place AL. The installationable place AL may be a place where the existing equipment 51 is installed.

Next, as shown in FIG. 3, the user selects the equipment information of the lighting device D desired by the user from the list of equipment information of the lighting device D which is the equipment 51, and the duct in the spatial data. Drag the equipment information of Rail R to the installation location.

The user can install the equipment information of the lighting device D at the installation location of the equipment information of the duct rail R, just as the lighting device D is installed on the duct rail R. Further, the user can adjust the installation position of the lighting device D within the range of the installation location of the equipment information of the duct rail R. As mentioned above, the equipment information of the duct rail R can be installed only in the place where it can be installed AL. That is, the equipment information of the lighting device D can also be installed only in the predetermined installable place AL.

In this way, the information processing device 1 according to the embodiment constructs a lighting environment in three dimensions using a lighting device registered on the network, simulates the constructed lighting environment on the network, and illuminates the environment. Display the design result. The customer can place the luminaire at a predetermined position by dragging the luminaire from the list in three dimensions. The luminaire can only be installed in a predetermined position. As soon as the customer completes the arrangement of all the lighting devices, the information processing device 1 performs a simulation on the network, receives the feedback of the result, and refers to the model of the lighting environment.

Further, the user may install the equipment information of the lighting device D in the place where the equipment D can be installed. In this case, the length, number, arrangement, etc. of the duct rails R are selected based on the lighting device D installed by the user. In the selection of the duct rail R, the quantity of the lighting device D, the power consumption, and the like are taken into consideration, but the selection may be made in consideration of the size and use of the room, the position of the fixtures, and the like. For example, when the fixture is a table, the length of the duct rail R is selected so as to cover the range of the table.

Further, the information processing device 1 according to the embodiment connects to a network when the lighting environment is constructed in three dimensions, and calculates an estimate and a delivery date. Specifically, the information processing device 1 provides a system for automatically answering an estimate by linking a system for constructing a lighting environment with a database in which the price, inventory quantity, and delivery date of the lighting device are registered.

Further, the information processing device 1 according to the embodiment calculates the nearest warehouse and delivery date by providing a database having information on the specifications (performance) and the installation location of the lighting device desired by the customer.

In the past, when delivering a lighting device to a customer, a field survey was conducted after the customer's request was input, the result of the lighting design was presented to the customer, and corrections were repeated for construction. However, there are few customers who can specify the detailed specifications (performance) of the lighting equipment, and the hopes input by the customers are often vague and ambiguous keywords such as "bright" and "work reform". Therefore, even if the lighting design is performed and the lighting environment is presented, the correction will be repeated. In addition, since the inventory and delivery date of the lighting device are confirmed during the lighting design, it may not be known at the initial stage that the lighting device is out of stock or has a long delivery date.

Therefore, in the information processing device 1 according to the embodiment, the customer provides a system for constructing the lighting environment in three dimensions, and the system is linked to the database of the lighting device. Further, the information processing device 1 according to the embodiment links a system for constructing a lighting environment in three dimensions and a database of the lighting device. Further, the information processing device 1 according to the embodiment provides a database capable of selecting a lighting device having specifications desired by a customer at an initial stage and confirming a delivery date.

According to this embodiment, it is possible to provide a lighting environment that is closest to the customer's image. Also, as soon as the lighting environment is decided, the delivery date and cost will be known. Furthermore, the warehouse in which the lighting equipment is in stock, the number of stocks, the delivery date at the time of manufacture, etc. can be known at an initial stage.

Next, a configuration example of the information processing system S according to the embodiment will be described with reference to FIG. FIG. 4 is a block diagram showing a configuration example of the information processing system S according to the embodiment. As shown in FIG. 4, the information processing system S includes an information processing device 1, a plurality of sensors 10, a facility management device 50, a facility 51, and a plurality of external devices 100. Further, in the information processing system S, the information processing device 1, the plurality of sensors 10, the equipment management device 50, the equipment 51, and the plurality of external devices 100 are communicably connected via a predetermined network N. NS. The network N is, for example, a LAN (Local Area Network) or a WAN (Wide Area Network) such as the Internet. Although the information processing device 1 is configured separately from the equipment management device 50, the equipment 51, and the external device 100, the information processing device 1 is integrated with the equipment management device 50 and the equipment 51, or is an external device. It may be integrally configured with 100.

The information processing device 1 is an information processing device that provides various information such as 3D model information to the external device 100, and is realized by a server device, a cloud system, or the like.

Further, the information processing device 1 can also change the equipment information arranged in the three-dimensional spatial data based on, for example, a drag operation from the external device 100. For example, the information processing device 1 examines the contents of the received drag operation and adjusts the installation position of the equipment 51 of the three-dimensional model installed in the space SP so as to obtain the lighting environment desired by the user.

Further, the information processing device 1 acquires information on various facilities including the facility 51 from the facility management device 50. Alternatively, the information processing device 1 may acquire information directly from the equipment 51 without going through the equipment management device 50.

Further, the information processing device 1 can also remotely operate the actual equipment 51 based on the result of changing the equipment information arranged in the three-dimensional spatial data, for example. For example, the information processing device 1 controls the equipment 51 by transmitting a control signal for controlling the equipment 51 to the equipment management device 50. Alternatively, the information processing device 1 may directly control the equipment 51 without going through the equipment management device 50. As a result, for example, when the equipment 51 is a hanging device having a baton, the raising / lowering position of the raising / lowering portion (the baton, the lighting device suspended from the baton, etc.) in the hanging device is changed. Further, when the equipment 51 is a slide mechanism to which the lighting device is attached, the horizontal position of the lighting device is changed by sliding the slide mechanism. Further, when the equipment 51 is a lighting device, the information processing device 1 can control the lighting and extinguishing of the lighting device via the equipment management device 50 or directly.

The sensor 10 is a sensor that measures data indicating the three-dimensional shape of the space SP, and is, for example, a 3D scanner, a camera, or the like. The image sensor used in the camera or the like is, for example, a CCD (Charge-Coupled Device) image sensor, a CMOS (Complementary Metal Oxide Semiconductor) image sensor, or the like. Further, the sensor 10 may include an illuminance sensor (optical sensor) for detecting ambient illuminance and various other sensors. Further, the sensor 10 is mounted on the ceiling / wall / floor surface of the space SP in the facility B and the equipment 51 installed in the space SP.

Further, the sensor 10 can measure the data of the space SP at an arbitrary timing. For example, the sensor 10 may periodically measure the data of the space SP at predetermined intervals, or may measure the data of the space SP when there is an instruction or a drag operation from the user. Further, the information processing system S includes, for example, a sensor (an example of a status detection sensor) that detects the status of the space SP such as a camera, and the sensor 10 is a case where the status change of the space SP is detected by the status detection sensor. , The data of the space SP is measured. As a result, for example, when the incidental equipment described later changes or the elevating position of the hanging device, which is the equipment 51, changes, the latest space SP data can always be measured by performing data measurement. .. Data indicating the three-dimensional shape of the space SP may be measured by the sensors 10 at a plurality of locations and transmitted to the information processing device 1. In this case, the sensor 10 is not permanently installed in the space SP, and one sensor 10 can be moved to a plurality of places to measure data. Further, the information processing device 1 may combine a plurality of measurement data transmitted from the sensor 10 to acquire one spatial data.

The equipment management device 50 manages the equipment 51. For example, the equipment management device 50 holds various information about the equipment 51. The equipment 51 is various equipment installed in the space SP, and is, for example, an electric lamp / lighting equipment such as a lighting device, equipment related thereto, and the like. That is, the equipment referred to here is equipment that can be retrofitted to the space SP, for example, excluding the equipment originally provided in the space SP such as windows and stairs.

The external device 100 is a terminal device owned by the user. For example, the external device 100 is a PC (Personal Computer), a smart device such as a smartphone or tablet terminal, or a terminal device such as a digital camera. Further, the external device 100 may be a glasses-type VR device such as a head-mounted display or smart glasses.

Further, the external device 100 includes a wireless communication network such as LTE (Long Term Evolution), 4G (4th Generation), 5G (5th Generation: 5th generation mobile communication system), Bluetooth (registered trademark), and wireless LAN (Local). It can be connected to the network N via short-range wireless communication such as Area Network) and communicate with the information processing device 1.

Next, a configuration example of the information processing apparatus 1 according to the embodiment will be described with reference to FIG. FIG. 5 is a functional block diagram showing a configuration example of the information processing device 1 according to the embodiment.

As shown in FIG. 5, the information processing device 1 includes a communication unit 2, a control unit 3, and a storage unit 4.

The communication unit 2 is a network device for performing wireless communication processing and wired communication processing. For example, the communication unit 2 transmits and receives various information to and from the sensor 10, the equipment management device 50, the equipment 51, and the external device 100 via a predetermined network N.

The control unit 3 includes an acquisition unit 31, a generation unit 32, a provision unit 33, a reception unit 34, and a change unit 35. The storage unit 4 stores the spatial data information 41 and the equipment information 42.

Here, the information processing device 1 is, for example, a computer having a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), a flash memory (Flash Memory), an input / output port, and various circuits. including.

The CPU of the computer functions as the acquisition unit 31, the generation unit 32, the provision unit 33, the reception unit 34, and the change unit 35 of the control unit 3, for example, by reading and executing the program stored in the ROM.

Further, at least one or all of the acquisition unit 31, the generation unit 32, the provision unit 33, the reception unit 34, and the change unit 35 of the control unit 3 are ASIC (Application Specific Integrated Circuit), FPGA (Field Programmable Gate Array), or the like. It can also be configured with the hardware of.

Further, the storage unit 4 is realized by, for example, a semiconductor memory element such as a RAM or a flash memory, or a storage device such as an HDD (Hard Disk Drive), an SSD (Solid State Drive), or an optical disk. The storage unit 4 may be an internal storage or an external storage. Further, the storage unit 4 may be a removable storage medium such as a USB memory or an SD (Secure Digital) memory card. Further, the storage unit 4 may be a cloud storage (online storage), a NAS (Network Attached Storage), a file server, or the like.

From the initial storage state, from the power consumption capacity such as cameras and sensors, if the user etc. later attaches a lighting fixture (other company's product etc.) that is not in the management list, it will be notified. In addition, from the initial memory state, from the usage status (brightness, lighting time) of the lighting equipment, regular notification of usage status, proposal of lighting design change, notification of renewal according to the usage status of the user, etc. You can.

Spatial data information 41, equipment information 42, information on various programs, and the like can be stored in the storage unit 4. The spatial data information 41 and the equipment information 42 may be a database. The information processing device 1 may acquire the above-mentioned program and various information via another computer or a portable recording medium connected by a wired or wireless network.

The spatial data information 41 stored in the storage unit 4 is information on the spatial data acquired by the acquisition unit 31 described later. FIG. 6 is a diagram showing an example of spatial data information 41. As shown in FIG. 6, the spatial data information 41 includes items such as “facility ID”, “facility type”, and “spatial data”.

The "facility ID" is identification information that identifies the facility in the spatial data. "Facility type" is information indicating the type of facility. "Spatial data" is information indicating spatial data.

The equipment information 42 stored in the storage unit 4 is information about the equipment 51 acquired from the equipment management device 50. For example, the equipment management device 50 acquires information about the equipment 51 in advance from a server device, a PC, or the like managed by a manufacturer or the like. Alternatively, the equipment management device 50 may be a server device, a PC, or the like managed by a manufacturer or the like. For example, the equipment management device 50 has information on the specifications (performance) of the lighting device which is the equipment 51, the warehouse in which the lighting device is in stock, the number of stocks, the delivery date when manufactured / transported, and the like. FIG. 7 is a diagram showing an example of equipment information 42. As shown in FIG. 7, the equipment information 42 includes items such as “equipment ID”, “equipment type”, and “detailed information”.

The "equipment ID" is identification information that identifies the equipment 51. The "equipment type" is information indicating the type of the equipment 51. "Detailed information" is information regarding the details of the equipment 51 registered in advance by the manufacturer or the like. The "detailed information" is information in which the information of the equipment 51 is three-dimensionally modeled. For example, the information of the three-dimensional shape based on the dimensional information of the equipment 51, and in the lighting device, the irradiation range and the irradiation intensity. Information in which lighting modes such as (light amount) and color temperature are three-dimensionally modeled is included. Further, the "detailed information" includes information on the warehouse in which the equipment 51 is in stock, the number of stocks, the delivery date at the time of manufacturing / transportation, and the like. Further, the "detailed information" includes information on the equipment cost when the equipment 51 is installed in the space SP.

Next, each function of the control unit 3 (acquisition unit 31, generation unit 32, provision unit 33, reception unit 34, and change unit 35) will be described.

The acquisition unit 31 acquires three-dimensional spatial data. Specifically, the acquisition unit 31 generates (acquires) spatial data by processing data indicating the three-dimensional shape of the spatial SP measured by the sensor 10 with predetermined software. The acquisition unit 31 may acquire spatial data from another server device that generates spatial data. The acquisition unit 31 stores the acquired spatial data as spatial data information 41 in the storage unit 4. As a result, for example, when installing or changing the equipment 51 or ancillary equipment, it is not necessary for the worker to actually go to the site to measure the data, so that the burden on the worker can be reduced.

The generation unit 32 sets the equipment 51 as a three-dimensional model for the spatial data acquired by the acquisition unit 31. For example, the generation unit 32 generates 3D model information in which the equipment information 42, which is a three-dimensional model of the information of the equipment 51 installed in the facility B, is set for the spatial data. In addition, the generation unit 32 generates 3D model information according to the user's drop operation. Specifically, when the generation unit 32 receives a drop operation for arranging the equipment information 42 of the equipment 51 in the spatial data from the user, the 3D model information in which the equipment information 42 of the equipment 51 that has been dropped is set in the spatial data. To generate. Thereby, for example, in the external device 100, the arrangement of the equipment 51 and the like can be simulated on the spatial data. Further, for example, when the equipment 51 is a lighting device, the generation unit 32 sets the lighting mode of the lighting device by modeling it in three dimensions. As a result, for example, the lighting mode of the lighting device can be simulated on the spatial data, so that the customer can easily grasp the image when the equipment 51 is installed in the spatial SP.

Further, the generation unit 32 generates 3D model information for displaying the spatial data and the equipment information 42 in the virtual space by the external device 100. For example, the generation unit 32 generates 3D model information for displaying the equipment 51 arranged in the spatial data in the virtual space based on the equipment information 42. Thereby, for example, a user wearing an external device 100 such as VR goggles can see the equipment information 42 installed in the spatial data which is a virtual space. That is, since the user feels as if he / she is actually in the space SP and is actually looking at the equipment 51, the customer can easily imagine the position and size of the equipment 51 when the equipment 51 is installed in the space SP. I can grasp it.

Further, the generation unit 32 generates 3D model information that displays the equipment information 42 as augmented reality in the space SP by the external device 100 based on the space data. As a result, for example, for a worker or the like who repairs the failed equipment 51, the equipment information 42 such as the restoration procedure is superimposed on the image of the equipment 51 displayed on the screen of the external device 100 as an augmented reality. Since it is not necessary for the person to carry a manual book or the like, the burden on the worker can be reduced.

Further, the generation unit 32 generates 3D model information in which the information of the incidental equipment installed together with the equipment 51 in the space SP is set as the information of the incidental equipment which is three-dimensionally modeled with respect to the spatial data. Ancillary equipment includes, for example, interiors such as furniture and curtains, home appliances, office furniture (desks, chairs, cabinets, archives, lockers, etc.), office equipment such as OA equipment, foliage plants, store fixtures such as display shelves, and in factories. It is a facility installed together with a lighting device which is a facility 51 in a space SP such as a production facility. Thereby, for example, by arranging the lighting device which is the equipment 51 on the spatial data in which the office equipment or the like is arranged, it is possible to easily confirm how the light of the lighting device is irradiated to the office equipment. be able to.

In addition, the generation unit 32 generates 3D model information with a predetermined position in the spatial data specified by the user as a virtual viewpoint. For example, the generation unit 32 generates 3D model information with the arrangement position of the equipment 51 as a virtual viewpoint. For example, the generation unit 32 uses the position of the lighting device, which is the equipment 51, as a virtual viewpoint, and generates 3D model information that virtually shows the state in which the irradiation direction is viewed from the lighting device. As a result, the user can confirm the arrangement position of the equipment 51 and confirm the irradiation mode while observing the irradiation direction from the lighting device.

Further, for example, the generation unit 32 sets a virtual viewpoint in another space where the space SP in which the equipment 51 is installed can be viewed, and provides 3D model information that virtually shows the state in which the space SP is viewed from the virtual viewpoint. Generate. As a result, the user can see an image of the equipment 51 installed in the space SP from another space. As a result, for example, the user desires from the list of equipment information that can be installed in the space SP based on the image of the space SP viewed from another space even though the user is outside the facility B. Equipment information can be selected and dragged.

The providing unit 33 provides the user (external device 100) with the 3D model information generated by the generating unit 32. That is, the providing unit 33 displays the 3D model information on the display unit or the like of the external device 100. For example, the providing unit 33 displays 3D model information that virtually shows the state in which the irradiation direction is viewed from the lighting device, which is the equipment 51, on the display unit or the like of the external device 100. Alternatively, the providing unit 33 displays 3D model information of the external device 100, etc., which virtually shows the state in which the space SP in which the equipment 51 is installed is viewed from a virtual viewpoint set in another space where the equipment 51 can be viewed. Display in.

Further, the providing unit 33 provides the user (external device 100) with the equipment information 42 arranged in the spatial data based on, for example, the 3D model information. Specifically, the providing unit 33 provides, for example, information on the specifications (performance) of the equipment 51 and the installation location according to the equipment information 42 arranged in the spatial data to the user (external device 100).

Further, the providing unit 33 provides the user with information on the in-stock warehouse, the number of stocks, and the delivery date of the equipment 51 according to the equipment information 42 arranged in the spatial data based on the 3D model information.

Further, the providing unit 33 calculates the equipment cost according to the equipment information 42 arranged in the spatial data based on the 3D model information, and provides the calculated equipment cost information to the user (external device 100).

Further, the providing unit 33 provides comparative information comparing the post-installation data, which is the spatial data after the equipment 51 is installed in the space SP, with the 3D model information generated by the generating unit 32. As a result, the user can compare the position of the equipment 51 in the simulated 3D model information with the position of the actually installed equipment 51 and confirm that there is no difference in the installation position.

The reception unit 34 receives various requests from the user via the external device 100. For example, the reception unit 34 receives a request for providing 3D model information from the user. When the reception unit 34 receives the provision request, the reception unit 34 provides the 3D model information to the user (external device 100) via the provision unit 33.

Further, the reception unit 34 receives the selection and drag operation of the equipment information 42 desired by the user from the list of the equipment information 42 that can be installed in the space SP from the user's external device 100. When the reception unit 34 accepts the selection and drag operation of the equipment information 42 desired by the user from the list of the equipment information 42 that can be installed in the space SP, the reception unit 34 generates the accepted drag operation. Alternatively, the change unit 35 is notified. For example, the reception unit 34 notifies the generation unit 32 when the 3D model information is first generated, and notifies the change unit 35 when the generated 3D model information is changed. It may be.

When the reception unit 35 accepts the selection and drag operation of the equipment information 42 desired by the user from the list of the equipment information 42 that can be installed in the space SP, the change unit 35 responds to the accepted drag operation. The equipment information 42 in the spatial data is changed. For example, the changing unit 35 changes the equipment 51 and the ancillary equipment of the three-dimensional model installed in the space SP by simulation on the space data according to the received drag operation. The change unit 35 updates the 3D model information based on the spatial data after the change. Alternatively, the generation unit 32 generates the updated 3D model information based on the spatial data after the change.

In this way, by changing the equipment information 42 in the spatial data according to the drag operation received by the changing unit 35, the lighting environment corresponding to the drag operation can be expressed by the 3D model information.

Next, with reference to FIG. 8, the flow of the process of providing the 3D model information executed in the information processing system S according to the embodiment will be described. FIG. 8 is a sequence diagram showing a flow of processing for providing 3D model information executed in the information processing system S according to the embodiment.

As shown in FIG. 8, the sensor 10 measures the data of the three-dimensional shape of the space SP of the facility B (step S101).

Subsequently, the sensor 10 transmits the measured data to the information processing device 1 (step S102). For example, the sensor 10 may transmit the measured data to the information processing device 1 via the server device or PC installed in the facility B.

Subsequently, the information processing apparatus 1 generates three-dimensional spatial data of the spatial SP by processing the data received from the sensor 10 by software (step S103).

Subsequently, the information processing apparatus 1 generates 3D model information by setting the equipment information 42 in which the information of the equipment 51 installed in the facility B is three-dimensionally modeled with respect to the generated spatial data ( Step S104). The 3D model information generated in step S104 is information in a state in which the equipment information 42 can be visually displayed with respect to the spatial data. In other words, the 3D model information in step S104 is temporarily displayed. If so, only the spatial data is displayed, and a list or the like for selecting the equipment information 42 to be set in the spatial data is displayed.

Subsequently, the information processing device 1 provides the generated 3D model information to the external device 100 (step S105). For example, the information processing device 1 provides 3D model information to the external device 100, and the user possessing the external device 100 can use the 3D model information for work support, 3D modeling, augmented reality (AR), simulation, and so on. Realize services such as virtual reality (VR).

Subsequently, the information processing device 1 accepts the selection and drag operation (drag and drop) of the equipment information desired by the user from the list of equipment information that can be installed in the space SP from the user's external device 100 (drag and drop). Step S106).

Subsequently, the information processing device 1 generates 3D model information according to the drag operation received from the external device 100 (step S107). For example, the information processing device 1 according to the embodiment changes the equipment information 42 installed in the space SP by simulation on the space data according to the received drag operation. Specifically, the installation position of the equipment of the 3D model is adjusted, the existing equipment is removed or replaced, and new equipment is added. Then, the information processing device 1 generates 3D model information in which the changed equipment information 42 is set.

The steps S106 to S107 may be performed before the steps S103 to S104. For example, when the information processing device 1 first generates 3D model information, the user's external device 100 selects the equipment information desired by the user from a list of equipment information that can be installed in the space SP. The drag operation may be accepted, and the equipment information installed in the space SP may be changed according to the accepted drag operation.

Subsequently, the information processing device 1 updates the 3D model information by providing the generated 3D model information to the external device 100 (step S108), and ends the process. That is, the information processing device 1 provides the external device 100 with the updated 3D model information.

As described above, the information processing apparatus 1 according to the embodiment according to the embodiment includes an acquisition unit 31, a generation unit 32, and a provision unit 33. The acquisition unit 31 acquires three-dimensional spatial data generated based on the data measured by the sensor 10 in the spatial SP in the predetermined facility B. The generation unit 32 generates 3D model information in which the equipment information 42, which is a three-dimensional model of the information of the equipment 51 installed in the facility B, is set for the spatial data acquired by the acquisition unit 31. The providing unit 33 provides the 3D model information generated by the generating unit 32 to the external device 100. Thereby, the convenience of the user can be improved.

Although embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. This embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. This embodiment and its modifications are included in the scope and gist of the invention, as well as in the scope of the invention described in the claims and the equivalent scope thereof.

1 Information processing device 2 Communication unit 3 Control unit 4 Storage unit 10 Sensor 31 Acquisition unit 32 Generation unit 33 Providing unit 34 Reception unit 35 Change unit 41 Spatial data information 42 Equipment information 50 Equipment management equipment 51 Equipment 100 External device S Information processing system

Claims (10)

With a reception unit that accepts drag operations of equipment desired by the user for three-dimensional spatial data indicating the space in a predetermined facility;
In response to the drag operation received by the reception unit, a 3D model in which the equipment information obtained by modeling the information of the equipment to be installed in the facility in a three-dimensional model is set in a predetermined installable place with respect to the spatial data. With a generator that generates information;
With a providing unit that provides the user with the 3D model information generated by the generating unit;
An information processing device characterized by comprising. The generator
The information according to claim 1, wherein the equipment information obtained by three-dimensionally modeling the information of the duct rail, which is the equipment, is set in the installable place to generate the 3D model information with respect to the spatial data. Processing equipment. The generator
The second aspect of claim 2, wherein the equipment information obtained by three-dimensionally modeling the information of the lighting device, which is the equipment, is set at the installation location of the duct rail to generate the 3D model information with respect to the spatial data. Information processing equipment. The generator
The information processing device according to claim 3, wherein the 3D model information in which the equipment information obtained by modeling the lighting mode of the lighting device in three dimensions is generated for the spatial data is generated. With the changing unit that changes the equipment information set in the 3D model information provided by the providing unit in response to the drag operation received by the receiving unit;
The information processing apparatus according to any one of claims 1 to 4, further comprising. The generator
Further, any of claims 1 to 5, wherein the 3D model information in which the incidental equipment information obtained by modeling the information of the incidental equipment installed together with the equipment is set with respect to the spatial data is generated. The information processing device according to one. The providing part
According to any one of claims 1 to 6, wherein the user is provided with information on the in-stock warehouse, the number of stocks, and the delivery date of the equipment arranged in the spatial data based on the 3D model information. The information processing device described. The providing part
The information processing apparatus according to any one of claims 1 to 7, wherein the user is provided with information on equipment costs according to the equipment arranged in the spatial data based on the 3D model information. .. With the acquisition unit that acquires three-dimensional spatial data based on the data measured by the sensor in the space in the predetermined facility;
Further equipped,
The generator
Claim 1 is characterized in that the 3D model information in which the equipment information is set is generated by three-dimensionally modeling the information of the equipment installed in the facility with respect to the spatial data acquired by the acquisition unit. The information processing apparatus according to any one of 8 to 8. It is an information processing method executed by an information processing device.
A reception process that accepts the drag operation of the equipment desired by the user for the three-dimensional spatial data indicating the space in the predetermined facility;
In response to the drag operation, a generation step of generating 3D model information in which the information of the equipment to be installed in the facility is three-dimensionally modeled with respect to the spatial data and the equipment information is set in a predetermined installable place. When;
With the providing process of providing the 3D model information to the user;
An information processing method characterized by including.

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