JP2015172614A - Information processing apparatus, information processing method, and multi-projection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To cause a plurality of projectors to project images by use of an information processing apparatus, in consideration of a positional relationship between the projectors, configured to easily associate the images to be projected with the projectors, thereby reducing workload.SOLUTION: A mobile terminal 3 is communicably connected to the plurality of projectors for projecting a composite projection image by arranging a plurality of sectioned projection images, and transmits sectioned image data to the projectors. The mobile terminal includes: a projector connection section which acquires a unique IP address or a device name from each of the projectors; an image allocation management section which manages the IP address or the device name acquired from the projectors, in association with sectioned image data ID indicating each of the sectioned image data; and a control section which transmits each of the sectioned image data corresponding to each of the sectioned image data ID to projectors corresponding to the IP address or the device name, to control the projectors.

Description

  The present invention relates to an information processing apparatus, an information processing method, and a multi-projection system suitable for managing setting information of a plurality of projectors in a mobile terminal.

  Conventionally, a multi-projection system is constructed by connecting a plurality of projectors and a personal computer PC. When constructing the system, the operator needs to adjust the physical conditions such as the positional relationship of each projector and the distance and angle with the projection plane after installing the projector and the PC. After the image to be projected is read and image processing such as division is applied, an instruction is issued to indicate where the divided images are to be projected by the projector. For this reason, in order to construct a multi-projection system, it is necessary to adjust a physical projector and to perform processing for managing an image projected on each projector.

  Patent Document 1 discloses a technique in which a plurality of projectors share setting information such as position information and automatically set each other for the purpose of reducing the burden on the operator. In Patent Document 1, the position information of the projectors is measured using a geomagnetic sensor, and the positional relationship between the projectors is determined. After that, a technology is disclosed in which setting information such as brightness and contrast set in the projector is shared by infrared communication, and the settings of each other are changed.

  Patent Document 2 discloses a technique for changing a range of an image to be projected based on information input from a terminal such as a tablet. Patent Document 2 discloses a technique in which when a user designates a range on a tablet, a position at which an image is projected in real time and a position at which no image is projected can be changed in real time.

However, since the conventional multi-projection system is often built on the premise of a PC, it has not been considered to be realized by a mobile terminal such as a smartphone or a tablet that has become popular in recent years.
In addition, since the mobile terminal is lighter and smaller than the PC, the degree of freedom of installation location can be increased. That is, a multi-projection system that can handle various usage scenes can be constructed at low cost.
However, since there are few mobile terminals on the premise that general mobile terminals are connected to a plurality of monitors or tablets, there is a problem that the work load at the time of installation increases.
A general OS such as Windows (registered trademark) often uses a virtual display function provided by the OS to connect to a plurality of projectors and to perform processing for associating an image with a projector to be projected. The system was constructed easily.
However, many mobile terminals such as smartphones and tablets are not provided with a function of connecting to a plurality of monitors and projectors. In other words, it is difficult to perform a process for associating a projector with an image to be projected from a general mobile terminal. As a result, in a multi-projection system using a device other than a PC, it is necessary to physically adjust the projector so as to project an image in the same manner as an input image, and there is a problem that it takes time to construct the system.

Japanese Patent Application Laid-Open No. 2004-133260 discloses that the position information of a projector is measured using a geomagnetic sensor, and setting is performed in consideration of the positional relationship of the projector. However, since the projector needs to be equipped with hardware such as a geomagnetic sensor and an infrared communication module, the problem that it is difficult to construct a multi-projection system using a device having a general hardware configuration has not been solved.
Patent Document 2 discloses that the range of an image projected by a projector is changed. However, the problem that the work load at the time of system construction becomes large due to physical adjustment of the positional relationship of a plurality of projectors has not been solved.
Therefore, the conventional technique has a problem that the work load at the time of system construction becomes large even when the arrangement of the projectors is changed.
Therefore, when a system including a plurality of projectors and an information processing apparatus is constructed, a configuration and a method that can reduce the work load are eagerly desired.
The present invention has been made in view of the above. As an object of the present invention, when projecting an image onto a plurality of projection apparatuses using an information processing apparatus, an image to be projected in consideration of the positional relationship of the projection apparatus An object of the present invention is to provide an information processing apparatus, an information processing method, and a multi-projection system that can be easily associated with a projection apparatus and can reduce a work load.

In order to solve the above-described problem, the invention described in claim 1 is connected to a plurality of projection devices that project a composite projection image by arranging a plurality of segment projection images, and transmits segment image data to each of the projection devices. Specific information acquisition means for acquiring specific device information from each of the projection devices,
The device information acquired from each of the projection devices, the management unit that associates and manages the divided image data ID representing each of the divided image data, and each of the divided image data corresponding to each of the divided image data IDs. Projection control means for controlling each projection apparatus by transmitting to each projection apparatus corresponding to the information.

  According to the present invention, when an image is projected onto a plurality of projection apparatuses using an information processing apparatus, the positional relationship of the projection apparatuses can be taken into account, and the projection image and the projection apparatus can be easily associated with each other. The work load when setting a plurality of projectors can be reduced.

1 is a diagram illustrating a configuration of a multi-projection system according to a first embodiment of the present invention. It is a block diagram which shows the structure of the mobile terminal 50 applicable to the multi-projection system which concerns on 1st Embodiment of this invention. (A) and (b) are the figures for demonstrating the process which changes the image projected in a multi-projection system. 4 is a flowchart for explaining an operation of the mobile terminal according to the first embodiment of the present invention. It is a sequence diagram for demonstrating the connection procedure from a mobile terminal to a projector. It is a sequence diagram for demonstrating the change process of the projection position in a multi-projection system. It is a block diagram which shows the structure of the mobile terminal applicable to the multi-projection system which concerns on 2nd Embodiment of this invention. (A) (b) is a schematic diagram for demonstrating the determination method of the positional relationship between projectors. FIG. 11 is a sequence diagram for describing image projection processing in the multi-projection system.

  An embodiment of the present invention will be described. The present invention has the following characteristics when setting position information and projection images in a multi-projection system using a mobile terminal such as a smartphone or a tablet. In short, an application that operates on a mobile terminal such as a smartphone or a tablet manages the information that associates the IP address, projection position ID, and segmented image data ID of each installed projector.

Embodiments of the present invention will be described with reference to the drawings.
<First Embodiment>
A multi-projection system 1 according to a first embodiment of the present invention will be described.
The configuration of the multi-projection system 1 will be described with reference to the overall configuration diagram shown in FIG.
In this embodiment, the multi-projection system 1 includes n (n is a natural number) projectors (projection devices) P1 to Pn, one mobile terminal (information processing device) 3, and a wireless LAN router 5, and includes a projector, The mobile terminal 3 communicates using a wireless LAN.
The projectors P1 to Pn comply with, for example, the IEEE 802.11a / b / g / n standard, receive image data such as still images and moving images transmitted from the mobile terminal 3 via the wireless LAN router 6, and the images Data is projected onto the projection surfaces M1 to Mn.
The mobile terminal 3 conforms to, for example, the IEEE 802.11a / b / g / n standard, and after connecting the setting information (IP address) of each projector, connects to the projectors P1 to Pn via the wireless LAN router 6. . Thereafter, image processing such as trimming or resolution conversion is performed on the image data serving as the input source, and the image data is transmitted to the projectors P1 to Pn via the wireless LAN router 6. The mobile terminal 3 is an information device including a camera such as a smartphone or a tablet.

The wireless LAN router 6 complies with, for example, the IEEE 802.11a / b / g / n standard, distributes IP addresses to the projectors P1 to Pn and the mobile terminal 3, establishes a wireless connection, and uses an IP packet to generate an image. Communicate data and management data.
The wireless LAN router 6 is generally a communication device that interconnects different networks, and is responsible for connection from the first layer (physical layer) to the third layer (network layer) according to the communication protocol. This router is a device that enables an IP packet (third layer) to be exchanged between networks as a basic function. In particular, in the present embodiment, communication path selection (routing) and data relay in the network are performed via the third layer (network layer). Further, signals are exchanged between communication devices connected directly (adjacent) via the second layer (data link layer). Furthermore, physical connection is performed via the first layer (physical layer).

  As a communication means, a wired LAN may be used instead of the wireless LAN. In this case, a LAN cable may be connected between the projectors P1 to Pn and the wireless LAN router 6, and the mobile terminal 3 and the wireless LAN router 6 may be connected by a wireless LAN. Further, the projectors P1 to Pn and the wireless LAN router 6 may be connected by a LAN cable, and the mobile terminal 3 and the wireless LAN router 6 may be connected by a LAN cable.

The configuration of the mobile terminal 3 will be described with reference to the block diagram shown in FIG.
The mobile terminal 3 includes a control unit 11, a display control unit 12, a display unit 13, a touch panel 14, an operation input unit 15, a camera unit 16, a wireless LAN control unit 17, a projector connection unit 18, an image allocation management unit 19, and an image allocation change. A unit 20, an image projection unit 21, a section test image generation unit 22, and a positional relationship determination unit 23.
The controller 11 includes a ROM (Read Only Memory), a RAM (Random Access Memory), a CPU (Central Processing Unit), and a timer. The CPU reads the operating system OS from the ROM, expands it on the RAM, starts the OS, reads a program (processing module) from the ROM under the management of the OS, and executes various processes.
The display control unit 12 stores the image data in a VRAM (not shown) and outputs it to the display unit 13 at a display rate. The display unit 13 expands and displays the image data input from the display control unit 12 on the liquid crystal panel.
The touch panel 14 is a transparent panel arranged on the upper surface of the display unit 13, detects a user's contact operation, and outputs an ON / OFF state to the operation input unit 15. The operation input unit 15 converts the ON / OFF state during the contact operation input from the touch panel 14 into coordinate information on the touch panel and outputs the coordinate information to the control unit 11. At this time, the control unit 11 analyzes the operation instruction based on the coordinate information from the operation input unit 15 and performs appropriate control.

The camera unit 16 captures a subject and outputs image data. The wireless LAN control unit 17 is compliant with, for example, the IEEE 802.11a / b / g / n standard, and establishes a wireless communication connection via the wireless LAN router 5 using the IP address distributed from the wireless LAN router 5. Then, image data and management data are communicated using IP packets.
The projector connection unit 18 communicates and connects to the wireless LAN router 5 from the wireless LAN control unit 17 in response to a command from the control unit 11 that receives an operation instruction from the user, and connects to the projector via the wireless LAN router 5. When the communication connection is successful, the projector connection unit 18 registers the IP address of the projector used for connection to the projector in the management table on the RAM 19a.
The image allocation management unit 19 stores the IP address or device name used when the projector connection unit 18 establishes a communication connection with the projector in the management table on the RAM 19a. Further, the image allocation management unit 19 associates (links) the projection position ID representing the projection position projected by the projector and the segment image data ID, and uniquely manages them in the management table on the RAM 19a.

The image assignment changing unit 20 changes the image assigned to each projector P1 to Pn when the image projected on the projector is different from the image data serving as the input source. The image assignment changing unit 20 changes the projection position ID and the segmented image data ID stored in the management table on the RAM 19a in accordance with an instruction from the user when the user needs.
After completing the adjustment of the projection position assignment, the image projection unit 21 outputs a projection instruction to the projector so as to project an image from the connected projector P. This projection instruction is transmitted from the wireless LAN control unit 17 to the wireless LAN router 5 and from the wireless LAN router 5 to the projector.
The section test image generation unit 22 generates section test image data that represents a section using numbers based on the section image data ID or the projection position ID. Further, the segment test image generation unit 22 outputs the arrangement order of the segment test image data to the positional relationship determination unit 23.
The positional relationship determination unit 23 refers to the arrangement order acquired from the section test image generation unit 22. The positional relationship determination unit 23 recognizes by character recognition processing from captured images (output from the camera unit 16) of all the projection planes M1 to M3 projected by, for example, the projectors P1, P2, and P3. To convert it to text data. Further, the positional relationship determination unit 23 determines the positional relationship between adjacent projectors by comparing the text data recognized as the arrangement order from the section test image generation unit 22.

With reference to the schematic diagrams shown in FIGS. 3A and 3B, processing for changing an image to be projected in the multi-projection system 1 will be described.
In the multi-projection system 1, when the image projected on the projector is different from the image data (3, 2, 1) serving as the input source 3a (1, 2, 3) (FIG. 3A), the user is mobile. Images assigned to the projectors P1 to Pn can be changed using the terminal 3.
FIG. 3A shows an example in which the “pre-adjustment” projected image is in an abnormal state, and the images projected on the projection plane M1 and the projection plane M3 are different from each other. In this case, the segment image data “3” (3a ₃ ) is assigned as the segment test image data to be projected from the projector P1 corresponding to the segment image data ID “1” of the “input image” 3a. Further, the divided image data “1” (3a ₁ ) is assigned to the projector P3 corresponding to the divided image data ID “3” of the “input image” 3a.
As shown in FIG. 3A, when the images on the left and right projection planes M1 and M3 are switched, it is an abnormal state in which the image cannot be projected according to the position arrangement of the input image data. The projection image is difficult to perform.

Therefore, in this embodiment, the user assigns the segmented image data “1” (3a ₁ ) to the projector P1 corresponding to the segmented image data ID “1” of the “input image” 3a. Further, the operation screen of the mobile terminal 3 is operated so that the segmented image data “3” (3a ₃ ) is assigned to the projector P3 corresponding to the segmented image data ID “3” of the “input image” 3a. The setting is changed for the management table stored on the RAM 19a.
As a result, as shown in FIG. 3B, as the image to be projected from the projector P1, the divided image data “1” (3a ₁ ) corresponding to the divided image data ID “1” of the “input image” 3a. Is assigned to the projector 3, and the divided image data “3” (3a ₃ ) is assigned to the projector 3 corresponding to the divided image data ID “3” of the “input image” 3a.
The image data can be projected so as to coincide with the “input image” 3a as in the normal state in which the “adjusted” projection image shown in FIG. As a result, a correct projection image that is easy for the user to check visually is obtained.
Thus, since the division test image data is image data including numbers representing the arrangement order of the projectors, the division image in the management table can be checked by visually confirming the division test image data projected on the projection plane from the projector. Whether the arrangement order of the data ID and the projection position ID is correct or not can be immediately determined.

The operation of the mobile terminal 3 according to the first embodiment of the present invention will be described with reference to the processing flow shown in FIG. In FIG. 4, the overall processing including the image assignment processing in the multi-projection system 1 will be described.
First, in step S <b> 10, the projector connection unit 18 reads setting information (IP address) from all projectors via the wireless LAN router 6. At this time, for a device wirelessly connected to the wireless LAN router 6, for example, a device that responds within a specified IP address range is searched. Note that the projector connection unit 18 acquires the IP address of the projector as device information when using the LAN connection.

  Next, in step S20, the mobile terminal 3 reads the IP address acquired as a search result and creates a management table shown in Table 1. Setting information (IP addresses) for the number of projectors used this time is stored in the management table on the RAM 19a and generated. For example, when the number of projectors connected to the network is relatively small (for example, about 1 to 10 or about 20), generally, the probability that only the rightmost number of the IP address is changed increases. Therefore, it is preferable to store the IP address in the management table in ascending order of the rightmost number.

Next, in step S30, the image allocation management unit 19 projects the projection position ID representing the projection position projected by the projector and the image projected by the projection apparatus for each IP address (apparatus information) stored in the management table on the RAM 19a. The section image data ID representing the data is uniquely associated and managed. For example, as an initial setting, the image allocation management unit 19 sets “1”, “2”,..., “1”, “2”,. n ”.
Next, in step S40, the control unit 11 acquires an IP address, a projection position ID, and a segmented image data ID from the management table on the RAM 19a. Then, the projector is controlled to project the segmented image by transmitting the segmented image data corresponding to the segmented image data ID to the projector specified by the IP address. As the segmented image, for example, an “input image” 3a which is the segmented test image data shown in FIGS. 3A and 3B is preferable. As a result, the respective division images projected onto the projection planes M1 to Mn from the projectors P1 to Pn are presented, and the user can visually confirm them.

Next, in step S50, the control unit 11 displays a message “Is the segmented test image projected from the projector correctly arranged?” And a button image representing the “Yes” button and the “No” button. 12 is output. As a result, the message, “Yes” button, and “No” button are displayed from the display unit 13.
When the user touches either the “Yes” button or the “No” button from the touch panel 14, the ON / OFF state at the time of the touch operation is output from the touch panel 14 to the operation input unit 15. The operation input unit 15 converts the ON / OFF state during the contact operation input from the touch panel 14 into coordinate information on the touch panel and outputs the coordinate information to the control unit 11. At this time, based on the coordinate information from the operation input unit 15, the control unit 11 analyzes whether or not there has been an operation instruction for the “Yes” button or the “No” button.
Next, in step S60, the control unit 11 determines whether to change the storage contents of the management table. That is, when the “No” button is touched, the control unit 11 needs to change the storage contents of the management table, and thus proceeds to step S70. On the other hand, when the “Yes” button is touched, the control unit 11 does not need to change the storage contents of the management table, and ends the process.

Next, in step S70, the image assignment changing unit 20 changes the projection position ID or / and the divided image data ID stored in the management table when the user needs them. That is, image data representing the contents of a management table (Table 1) described later is output to the display control unit 12. As a result, an image representing the contents of the management table (Table 1) is displayed on the display unit 13.
When the user performs a touch operation on a desired position on the content image of the management table from the touch panel 14, a soft keyboard is displayed on the display unit 13. When the user performs a touch operation on a numeric key corresponding to a correct number on the soft keyboard, the control unit 11 recognizes the key code of the touched numeric key based on the coordinate information from the operation input unit 15 and stores the key code on the RAM 19a. The number is stored in the management table. By repeating such an operation, the management table on the RAM 19a is corrected, and an appropriate arrangement of the projection position ID and / or the segmented image data ID can be obtained. When the process in step S70 is completed, the process returns to step S40.
Next, in step S40, the control unit 11 acquires the IP address, the projection position ID, and / or the segmented image data ID from the management table (after change) on the RAM 19a. Then, the projector is controlled to project the segmented image by transmitting the segmented image data corresponding to the segmented image data ID to the projector specified by the IP address. As a result, the respective divided images projected onto the projection planes M1 to Mn from the projectors P1 to Pn are presented, and the user can visually confirm each of the projected divided images again.

A connection procedure from the mobile terminal 3 to the projector P will be described with reference to the sequence diagram shown in FIG.
In the multi-projection system 1, a process of creating a management table (10) for managing a projection destination projector P and an image to be projected will be described as an example where three projectors P1 to P3 are connected.
First, the user issues a connection instruction to the projector P1 to the mobile terminal 3 (Se1).
The mobile terminal 3 accepts an operation instruction by a touch operation on the touch panel 14 from the user, communicates with the wireless LAN router 5 from the wireless LAN control unit 17, and connects to the projector 1 via the wireless LAN router 5 (Se3). .

If the communication connection is successful, the mobile terminal 3 uses the information used for connection to the projector P1 and registers it in the management table. Since the projector is the first connected, “1” is set as the projection position ID (Se5). In sequence Se5, the segmented image data ID, IP address, device name, and projection position ID acquired at the time of connection in sequence Se3 are stored in the management table on RAM 19a.
Next, after the connection to the projector P1 is completed, the same processing is performed for the projectors P2 and P3, and “2” and “3” are respectively set as the projection position ID (Se7 to Se13).
Similarly, even when the number of projectors is three or more, sequential connection to the projector and registration processing in the management table on the RAM are performed. At that time, the projection position ID is uniquely assigned.

  Next, information managed in the management table shown in Table 1 will be described.

In the management table shown in Table 1, as setting items, segmented image data ID for uniquely managing the association between the projector to be projected and the image, the IP address of the projector to be projected, the device name of the projector to be projected, and the projection A projection position ID representing the position is stored.
In the multi-projection system 1, the information processing apparatus serving as the projection source manages the information defined in Table 1 as information related to the projection destination projector. Information defined in Table 1 is generated for each projector to be connected according to control by a program in the mobile terminal 3 and managed in a table format.
The mobile terminal 3 manages the information of the projection destination projector based on the IP address and the device name. When connecting via a network, the projector as a projection destination is managed by an IP address. In addition, when not managing using an IP address or a device name, a new identification means can be added separately.
Projection destination positions are allocated by the number of projectors to be connected, and do not overlap among a plurality of projectors.
Note that the addition of the record to the management table is performed when the mobile terminal 3 is connected to the projector. When communication between the mobile terminal 3 and the projector is disconnected, or when application software executed on the mobile terminal 3 is terminated, the record is discarded.

With reference to the sequence diagram shown in FIG. 6, the projection position changing process in the multi-projection system 1 will be described. Here, an example in which the mobile terminal 3 is connected to three projectors will be described.
First, the user operates the touch panel 14 of the mobile terminal 3 and issues an operation instruction (Se21).
The mobile terminal 3 receives an operation instruction by a touch operation on the touch panel 14 from the user, connects to the projector P1, and transmits a segmented image of the segmented test image data to the projector P1 (Se23).
The segment test image data transmitted by the mobile terminal 3 includes data generated based on the segment image data ID / projection position ID information in the allocation table.
The projector projects the image data received from the mobile terminal 3 via the wireless LAN router 5 onto the projection plane (Se25).
In Se27 to Se33, processing similar to Se23 and Se25 is performed. As a result, the divided images of the divided test image data are projected from the projectors P1, P2, and P3 onto the projection surfaces M1, M2, and M3, respectively.
In this way, the mobile terminal 3 can control the projector on a trial basis by transmitting the section test image data representing the reference array of the section image data to the projector.

After the segmented test image data projection process is completed, the touch panel 14 of the mobile terminal 3 is operated to change the image projection destination projector, and an operation instruction is issued (Se41).
First, an operation instruction for determining the positional relationship between the projectors P1 and P2 is issued (Se43).
The user uses the mobile terminal 3 to capture a segment test image of the projector P1 with the camera unit 16 (Se45). Next, the division test image of the projector P2 is taken by the camera unit 16 (Se47).
Next, an operation instruction for determining the positional relationship between the projectors P2 and P3 is issued (Se49).
The user uses the mobile terminal 3 to capture a segment test image of the projector P2 with the camera unit 16 (Se51). Next, the division test image of the projector P3 is taken by the camera unit 16 (Se53).

Next, after the mobile terminal 3 reads an image captured by the camera unit 16, the mobile terminal 3 automatically determines the projection position of the image and updates the image position assignment table (Se55).
Here, the automatic determination process will be described.
The segment test image generation unit 22 generates segment test image data (FIGS. 3 and 3a) representing numbers based on the segment image data ID and the projection position ID. Further, the segment test image generation unit 22 outputs the arrangement order of the segment test images to the positional relationship determination unit 23.
The positional relationship determination unit 23 refers to the arrangement order acquired from the section test image generation unit 22. The positional relationship determination unit 23 recognizes by character recognition processing from captured images (output from the camera unit 16) of all the projection planes M1 to M3 projected by, for example, the projectors P1, P2, and P3. To convert it to text data. Furthermore, the positional relationship determination unit 23 determines the positional relationship between adjacent projectors by comparing the arrangement order from the section test image generation unit 22 with the recognized text data.
In this comparison result, when the arrangement order from the division test image generation unit 22 and the recognized text data match, it can be confirmed that the arrangement of the division image data ID and the projection position ID is correct. .

On the other hand, in this comparison result, when the arrangement order from the section test image generation unit 22 and the recognized text data do not match, it is confirmed that the section image data ID and the projection position ID are misplaced. be able to.
As a result, the positional relationship of the projector can be grasped.
When the text information cannot be recognized from the captured image, as described above, the management table may be displayed on the display unit 13 of the mobile terminal 3, and the user may manually update the management panel to update the management table. .
According to the present embodiment, when projecting an image onto a plurality of projectors using a mobile terminal, it is possible to easily associate the projected image with the projector in consideration of the positional relationship of the projector. The load can be reduced.

Second Embodiment
A mobile terminal 50 applicable to the multi-projection system according to the second embodiment of the present invention will be described.
In the first embodiment, the configuration example is illustrated such that the correctness of the arrangement order for the divided image data ID and the projection position ID in the management table is determined by the character recognition process. However, the present invention is limited to such a configuration example. For example, a two-dimensional barcode can be used.
The multi-projection system according to the second embodiment is different from the first embodiment in that a division test image generation unit 51 and a positional relationship determination unit 52 are newly provided.

FIG. 7 is a block diagram showing a configuration of a mobile terminal 50 applicable to the multi-projection system according to the second embodiment of the present invention. 7 that are the same as those shown in FIG. 2 have the same configuration, and thus the description thereof is omitted.
The section test image generation unit 51 generates section test image data including identification information of a two-dimensional barcode generated from the section image data ID and the projection position ID. Further, the segment test image generation unit 51 outputs the arrangement order of the identification information of the two-dimensional barcode included in the segment test image data to the positional relationship determination unit 52.
The positional relationship determination unit 52 refers to the arrangement order of the identification information acquired from the section test image generation unit 22. The positional relationship determination unit 52 is a two-dimensional barcode or the like from captured images (output from the camera unit 16) of all the projection surfaces M1 to M3 projected by the user, for example, projected by the projectors P1, P2, and P3. Is recognized by a known two-dimensional barcode recognition process and converted into text data. Further, the positional relationship determination unit 52 determines the positional relationship between adjacent projectors by comparing the arrangement order of the identification information with the recognized text data.

A method for determining the positional relationship between projectors will be described with reference to schematic diagrams shown in FIGS.
The section test image is projected simultaneously from a plurality of projectors so that the positional relationship can be determined. A projector that does not project the segment test image projects a plain image. After projecting the segmented test image, the user captures images so that the projection planes M1 to M3 of all the projectors are within the angle of view of the camera unit 16 of the mobile terminal 3. The positional relationship between the projectors can be determined by repeating this operation at least (n−1) times. (N: Number of projectors)
In the sequence diagram shown in FIG. 5, as shown in FIG. 8A, projectors P1 and P2 are used when projecting the first section test image. Identification information such as a two-dimensional barcode generated from the image data ID and the division image data ID and the projection position ID in the management table is displayed on the division test image. The user photographs all the projection surfaces M1 to M3 of the projectors P1, P2, and P3 at a time. Thereby, the positional relationship between the projectors P1 and P2 is determined.
As shown in FIG. 8B, the second section test image is projected from the projectors P2 and P3. As with the first section test image, the user captures images so that all projection planes of the projectors P1, P2, and P3 are within the angle of view of the camera unit 16 of the mobile terminal 3. Thereby, the positional relationship between the projectors P2 and P3 can be determined.

That is, the segment test image generation unit 22 generates segment test image data including identification information of a two-dimensional barcode generated from the image data ID and the projection position ID. In addition, the segment test image generation unit 22 outputs the arrangement order of the identification information of the two-dimensional barcode included in the segment test image data to the positional relationship determination unit 23.
The positional relationship determination unit 23 refers to the arrangement order of the identification information acquired from the section test image generation unit 22. The positional relationship determination unit 23 uses well-known two-dimensional identification information such as a two-dimensional barcode from images projected on all the projection planes M1 to M3 of the projectors P1, P2, and P3 taken by the camera unit 16 by the user. Recognized by barcode recognition processing and converted to text data. The positional relationship determination unit 23 determines the positional relationship between adjacent projectors by comparing the arrangement order of the identification information with the recognized text data.
In this comparison result, when the arrangement order of the identification information matches the recognized text data, it can be confirmed that the arrangement of the segmented image data ID and the projection position ID is correct.
On the other hand, in this comparison result, if the arrangement order of the identification information and the recognized text data do not match, it can be confirmed that the arrangement of the divided image data ID and the projection position ID is incorrect.
As a result, the positional relationship of the projector can be grasped.

In this way, segment test image data including the two-dimensional barcode generated from the segment image data ID and the projection position ID is generated, and the arrangement order of the two-dimensional barcodes included in the segment test image data is output to the projector. Transmitting and projecting the segmented test image, capturing the segmented test image projected from the projector, recognizing the two-dimensional barcode from the captured image and converting it to text data, and further acquiring the array By comparing the order and the recognized text data, it is possible to automatically determine by determining the positional relationship between adjacent projectors, so that the divided image data ID and projection position ID in the management table can be determined. It is possible to determine whether or not the arrangement order is correct.
As described above, since the segment test image is an image including a two-dimensional barcode generated from the segment image data ID and the projection position ID, the segment test image projected on the projection plane from the projector is captured by the camera unit 16, Since it can be automatically determined by the positional relationship determination unit 23, it is possible to determine whether the arrangement order of the divided image data ID and the projection position ID in the management table is correct.

The image projection processing in the multi-projection system 1 will be described with reference to the sequence diagram shown in FIG.
First, after completing the assignment of the projection position, the user issues an image data projection instruction to the mobile terminal 3 (Se61).
After the mobile terminal 3 reads the input image serving as the input source (Se63), the mobile terminal 3 starts projection (Se65). Next, the mobile terminal 3 generates segment test image data to be projected on the projector P1 based on the segment image data ID and the projection position ID in the management table (Se67). Next, the mobile terminal 3 transmits the generated segment test image data to the projector P1 (Se69), and the projector P1 projects the image data received from the mobile terminal 3 onto the projection plane M1 (Se71).
In Se73 to Se77, the same processing as Se67 and Se71 is performed. As a result, the segment test image is projected from the projector P2 onto the projection surface M2.
Further, in Se79 to Se83, the same processing as Se73 and Se77 is performed. As a result, the segment test image is projected from the projector P3 onto the projection surface M3.
According to the present embodiment, when projecting an image onto a plurality of projectors using a mobile terminal, it is possible to easily associate the projected image with the projector in consideration of the positional relationship of the projector. The load can be reduced.

<Other embodiments>
In the first embodiment and the second embodiment, the projector connection unit 18 that acquires a unique IP address from each projector via the wireless LAN router 5, the IP address acquired from each projector, and each divided image The image allocation management unit 19 that manages the segmented image data ID representing the data in association with each other, and controls each projector by transmitting each segmented image data corresponding to each segmented image data ID to each projector corresponding to each IP address. The example of a structure provided with the control part 11 to perform was illustrated.

However, the present invention is not limited to such a configuration example. For example, Bluetooth (registered trademark) may be used instead of the wireless LAN. In this case, the wireless LAN router 6 is not necessary, and the projectors P1 to Pn and the mobile terminal 3 are directly wirelessly connected.
Moreover, the projector connection part 18 should just acquire the device name of a projector as apparatus information, when utilizing a Bluetooth connection. When connecting by Bluetooth means, the projection destination projector is managed based on the device name.
Specifically, a projector connection unit 18 that acquires a unique device name from each projector, an image assignment management unit 19 that manages a device name acquired from each projector and a segment image data ID that represents each segment image data, It can be configured to include a control unit 11 that controls each projector by transmitting each segment image data corresponding to each segment image data ID to each projector corresponding to the device name.
Accordingly, when projecting images onto a plurality of projectors using the mobile terminal 3, it is possible to easily associate the projected image with the projector in consideration of the positional relationship of the projectors, and to set a plurality of projectors. Can reduce the workload.

<Examples of Embodiments and Effects of the Present Invention>
<First aspect>
The mobile terminal 3 of this aspect is a mobile terminal that communicates and connects with a plurality of projector projectors that project a composite projection image by arranging a plurality of segment projection images, and transmits segment image data to each projector. A projector connection unit 18 that acquires a unique IP address or device name; an image assignment management unit 19 that manages an IP address or device name acquired from each projector and a segment image data ID that represents each segment image data; And a control unit 11 that controls each projector by transmitting each section image data corresponding to each section image data ID to each projector corresponding to each IP address or device name.
According to this aspect, when projecting an image onto a plurality of projectors using the mobile terminal 3, it is possible to easily associate the projected image with the projector in consideration of the positional relationship of the projector. The workload when setting the projector can be reduced.

<Second aspect>
The mobile terminal 3 according to this aspect includes an image assignment changing unit 20 that changes each divided image data ID when necessary.
According to this aspect, even when the “pre-adjustment” projection image is in a complicated state, it is changed to a normal state in which the projection image is normalized by changing each segment image data ID when necessary. be able to.
<Third aspect>
The projector connection unit 18 according to this aspect is characterized in that the IP address or device name of each projector is acquired as each device information.
According to this aspect, image assignment can be managed in association with information unique to each projector.

<4th aspect>
The control unit 11 according to this aspect is characterized in that each projector is controlled on a trial basis by transmitting, to each projector, section test image data representing a reference array of each section image data.
According to this aspect, it is possible to determine whether or not the “pre-adjustment” projection image is in an unusual state by visually confirming the segmented test image projected from each projector.
<5th aspect>
Each section test image data according to this aspect is an image including a number representing the arrangement order of the projectors.
According to this aspect, it is possible to determine whether or not the “pre-adjustment” projection image is in a complicated state by visually confirming the image including the numbers projected from each projector.

<Sixth aspect>
Each section test image data of this aspect is an image including a two-dimensional barcode generated from the section image data ID.
According to this aspect, the image including the two-dimensional barcode projected from each projector is photographed with the mobile terminal 3, and the segmented image data ID represented by the two-dimensional barcode can be confirmed. It is possible to determine whether or not the projected image of “is a complicated abnormal state.
<Seventh aspect>
The mobile terminal 3 of this aspect generates a segment test image data including a two-dimensional barcode representing each segment image data ID, and outputs an array order of the two-dimensional barcodes included in each segment test image data An image generation unit 51, a camera unit 16 that captures a section test image projected from each projector, and a positional relationship determination unit that recognizes a two-dimensional barcode from the captured image captured by the camera unit 16 and converts it into text data 52, and a positional relationship determination unit 52 that determines the positional relationship between the adjacent projectors by comparing the arrangement order acquired from the section test image generation unit and the text data recognized by the text recognition unit. It is characterized by that.
According to this aspect, the image including the two-dimensional barcode projected from each projector is photographed with the mobile terminal 3, and the segmented image data ID represented by the two-dimensional barcode can be confirmed. It is possible to determine whether or not the projected image of “is a complicated abnormal state.

<Eighth aspect>
The image allocation management unit 19 of this aspect is characterized in that instead of the segmented image data ID, a projection position ID representing a projection position projected by each projector is managed in association with each IP address.
According to this aspect, even when the projection position ID representing the projection position projected by each projector is incorrect and the “pre-adjustment” projection image is in an abnormal state complicated, each projection position ID is set when necessary. By changing, it is possible to change to a normal state in which the projection image is normalized.
<Ninth aspect>
The multi-projection system of this aspect includes a mobile terminal 3 and a plurality of projectors P1 to Pn.
According to this aspect, in the multi-projection system including the mobile terminal 3 and the plurality of projectors P1 to Pn, the positional relationship between the projectors is taken into account when the mobile terminal 3 is used to project an image onto a plurality of projectors. In addition, it is possible to easily associate the image to be projected with the projector, and it is possible to reduce the work load when setting a plurality of projectors.

<10th aspect>
The information processing method according to the mobile terminal 3 of this aspect is an information processing method in which a plurality of segmented projection images are arranged to communicate with a plurality of projectors that project a composite projection image, and segmented image data is transmitted to each projector. Step S10 for acquiring a unique IP address or device name from a plurality of projectors, and Step S30 for managing the IP address or device name acquired from each projector in association with the section image data ID representing each section image data And step S40 for controlling each projector by transmitting each segment image data corresponding to each segment image data ID to each projector corresponding to each IP address or device name.
According to this aspect, when projecting an image onto a plurality of projectors using the mobile terminal 3, it is possible to easily associate the projected image with the projector in consideration of the positional relationship of the projector. The workload when setting the projector can be reduced.

DESCRIPTION OF SYMBOLS 1 ... Multi-projection system, 3 ... Mobile terminal, 5 ... Wireless LAN router, 11 ... Control part, 12 ... Display control part, 13 ... Display part, 14 ... Touch panel, 15 ... Operation input part, 16 ... Camera part, 17 ... Wireless LAN control unit, 18 ... projector connection unit, 19 ... management unit, 20 ... change unit, 21 ... image projection unit, 22 ... section test image generation unit, 23 ... positional relationship determination unit, P1-Pn ... projector, 51 ... Section test image generation unit, 52... Positional relationship determination unit

JP2013-080088A JP 2009-223331 A

Claims (10)

An information processing apparatus that communicates and connects with a plurality of projection devices that project a composite projection image by arranging a plurality of segment projection images, and transmits segment image data to each of the projection devices,
Unique information acquisition means for acquiring unique device information from each of the projection devices;
Management means for associating and managing apparatus information acquired from each of the projection apparatuses and a section image data ID representing each section image data;
Projection control means for controlling the projection devices by transmitting the segment image data corresponding to the segment image data IDs to the projection devices corresponding to the device information. Information processing apparatus.   2. The information processing apparatus according to claim 1, further comprising changing means for changing each of the divided image data IDs when necessary.   The information processing apparatus according to claim 1, wherein the unique information acquisition unit acquires an IP address or a device name of each projection apparatus as each apparatus information. The projection control means includes
The information processing apparatus according to claim 1, wherein each projection apparatus is controlled on a trial basis by transmitting section test image data representing a reference array of each section image data to each projection apparatus.   The information processing apparatus according to claim 4, wherein each of the division test image data is an image including a number representing an arrangement order of the projection apparatuses.   5. The information processing apparatus according to claim 4, wherein each of the division test image data is an image including a two-dimensional barcode generated from the division image data ID. Section test image generation means for generating section test image data including a two-dimensional barcode representing each section image data ID and outputting an array order of two-dimensional barcodes included in each section test image data;
Camera means for taking a section test image projected from each projection device;
Text recognition means for recognizing a two-dimensional barcode from a photographed image photographed by the camera means and converting it into text data;
A positional relationship determination unit that determines the positional relationship between the adjacent projection devices by comparing the arrangement order acquired from the section test image generation unit and the text data recognized by the text recognition unit. The information processing apparatus according to claim 1. The management means includes
The projection position ID representing a projection position projected by each of the projection devices is managed in association with the device information instead of the segmented image data ID. Information processing device.   A multi-projection system comprising the information processing apparatus according to claim 1 and a plurality of projection apparatuses. An information processing method for communicating with a plurality of projection devices that project a composite projection image by arranging a plurality of segment projection images and transmitting segment image data to each of the projection devices,
A unique information acquisition step of acquiring unique device information from the plurality of projection devices;
A management step of associating and managing apparatus information acquired from each of the projection apparatuses and a section image data ID representing each section image data;
A projection control step of controlling each projection device by transmitting each segment image data corresponding to each segment image data ID to each projection device corresponding to each device information. Information processing method.

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