This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2018-009007 filed Jan. 23, 2018.
The present invention relates to an information processing apparatus, an information processing system, and a non-transitory computer readable medium storing a program.
There is a technology in which light beams are crossed in the air to form an image at the intersection of the light beams. The image displayed by using this type of technology is also referred to as an aerial image.
According to an aspect of the invention, there is provided an information processing apparatus including a detector that detects a direction of movement of a user relative to an image formed in an air, and a controller that controls formation of the image based on the detected direction.
Exemplary embodiments of the present invention will be described in detail based on the following figures, wherein:
Exemplary embodiments of the present invention are described below with reference to the drawings.
In this exemplary embodiment, an aerial image 10 is an image formed in the air so as to reproduce the state of light that is equivalent to light reflected from an object.
The aerial image 10 is formed so as to float in the air and therefore a person may pass through the aerial image 10.
For example, the aerial image 10 shows a guidance or advertisement screen. For example, the aerial image 10 shows an operation screen for changing display contents in response to an operation performed by a person 20. Those screens are examples.
The aerial image 10 may show a moving image as well as a still image.
In each exemplary embodiment, the entire rectangle is rendered as the aerial image 10 but the shape that defines the outer edge of the aerial image 10 is not limited to the rectangle and any other shape may be used. For example, a space where an image of an object is formed may be set as the entire space where the aerial image 10 is formed. For example, an image of an operation button, an image of a person, an image of an animal, an image of a product, and an image of a fruit are examples of the aerial mage 10. In
At present, the aerial image 10 is formed at a position specified in advance and at an angle specified in advance. Therefore, the person 20 needs to adjust his or her position to the formed aerial image 10.
In this exemplary embodiment, this relationship is reversed and the position and the angle of formation of the aerial image 10 are adjusted to the position of the person 20. In this exemplary embodiment, the display contents and the way to display the contents are also changed as necessary.
The aerial image forming system 1A illustrated in
The aerial image forming apparatus 31 is an example of an image forming unit. The image control apparatus 32A is an example of a controller. The image control apparatus 32A is also an example of an information processing apparatus. The position detecting sensor 33 is an example of a detector.
The image control apparatus 32A controls the formation of the aerial image 10 based on a moving direction of the person 20 (for example, a direction 1, a direction 2, or a direction 3) to increase the visibility of the aerial image 10. In other words, the image control apparatus 32A controls the position and the orientation of the formation of the aerial image 10 based on the movement of the person 20 to prevent a decrease in the visibility.
The image control apparatus 32A acquires the position of the person 20 based on a signal output from the position detecting sensor 33 and acquires an approaching direction of the person 20 through a history of the identified position of the person 20. The position of the person 20 need not be identified as precise coordinates but may be identified roughly.
The image control apparatus 32A controls the formation of the aerial image 10 so that the front side of the aerial image 10 is displayed for a specific person 20.
For example, the front side is a side where characters are recognized in a proper direction or a face is observed with its sides positioned properly. When the aerial image 10 is a three-dimensional image, the front side is a side where a surface defined as the front surface of the three -dimensional image is observed.
The position detecting sensor 33 is arranged so as to detect the person 20 who moves around the aerial image 10. The aerial image 10 may be formed ahead of a corner of a walkway and therefore the position where the position detecting sensor 33 is arranged is not limited to a space where the aerial image 10 may be recognized straight ahead. The number of position detecting sensors 33 is not limited to one but plural position detecting sensors 33 may be provided.
As the position detecting sensor 33, for example, a thermopile infrared sensor, a pyroelectric infrared sensor, a sensor that detects the presence or absence of an object that interrupts an infrared ray or the like (so-called optical sensor), an acoustic sensor that detects an object through a response of sound, a sensor that detects a load on a floor or mat, or an image capturing camera that captures an image of the person 20 who moves around the aerial image 10 may be employed depending on purposes and the arrangement space.
The position detecting sensor 33 may have a function of measuring a distance to the person 20. A sensor that measures a distance to the person 20 may be prepared separately from the position detecting sensor 33.
To measure a distance, for example, there may be used an optical method for measuring a distance through light reflection on an object, an ultrasonic method that uses an ultrasonic wave of 20 kHz or higher, a method for determining a distance by using parallax between two images that are captured stereoscopically by using two image capturing cameras, or a method for detecting a distance by capturing an image with blurring and color misregistration caused in accordance with the distance by using a single image capturing camera and performing image processing on the blurring and color misregistration.
The principles of formation of the aerial image 10 are described with reference to
The optical plate 42 has a structure in which a plate having strips of glass 42A arrayed so that their wall surfaces are used as mirrors and a plate having strips of glass 42B arrayed in a direction orthogonal to the strips of glass 42A are stacked vertically.
The optical plate 42 reflects the light beams output from the display device 41 twice on the strips of glass 42A and 42B to form an image in the air. Thus, an image displayed on the display device 41 is reproduced in the air. The distance between the display device 41 and the optical plate 42 is equal to the distance between the optical plate 42 and the aerial image 10. The dimensions of the image displayed on the display device 41 are equal to the dimensions of the aerial image 10.
In the case of the aerial image forming apparatus 31D, light beams output from the display device 45 are reflected by the beam splitter 46 in a direction to the retroreflective sheet 47 and then retroreflected by the retroreflective sheet 47. The light beams pass through the beam splitter 46 to form an image in the air. The aerial image 10 is formed at a position where the image is formed by the light beams.
In the case of the aerial image forming apparatus 31E, an infrared pulse laser 48 outputs a pulsed laser beam and an XYZ scanner 49 condenses the pulsed laser beam in the air. At this time, gas near a focal point is instantaneously turned into plasma to emit light. For example, the pulse frequency is 100 Hz or lower. For example, the pulse emission time is of the order of nanoseconds. The infrared pulse laser 48 and the XYZ scanner 49 are examples of the optical component.
The image control apparatus 32A includes a central processing unit (CPU) 51 that provides various functions through execution of firmware and application programs, a read only memory (ROM) 52, which is a storage area that stores the firmware and a basic input output system (BIOS), and a random access memory (RAM) 53, which is an area where the programs are executed. The CPU 51, the ROM 52, and the RAM 53 are examples of a so-called computer.
The image control apparatus 32A includes a storage device 54 that stores data of the application programs and the like. As the storage device 54, for example, a rewritable non-volatile storage medium is used for storing information.
The image control apparatus 32A controls the aerial image forming apparatus 31 by using a communication interface (communication IF) 55 to change the formation of the aerial image 10. The control includes control of the position where the aerial image 10 is formed and the dimensions of the aerial image 10. The position includes not only a two-dimensional position but also a three -dimensional position.
The image control apparatus 32A communicates with the position detecting sensor 33 by using an interface (IF) 56.
The CPU 51 and the respective parts are connected to each other through a bus 57.
The functional configuration illustrated in
The CPU 51 functions as a position detecting part 60 that detects the position of the person 20 (see
The position detecting part 60 detects the position of the person 20 based on information input from the position detecting sensor 33. The position is not limited to coordinates in the space but a predetermined range may be provided as a unit or a direction or distance to the aerial image 10 may be provided. The position of the person 20 is basically a two-dimensional position but may be a three -dimensional position when a height difference is present in a movement path due to stairs, bumps, or the like.
The moving direction detecting part 61 detects a direction of movement relative to the aerial image 10 based on, for example, a history of information on the position detected by the position detecting part 60. When the position detecting sensor 33 is an image capturing camera, the moving direction of the person 20 may be detected by processing image data.
For example, the moving direction of the person 20 includes a direction in which the person 20 approaches the aerial image 10, a direction in which the person 20 passes by the front of the aerial image 10, and a direction in which the person 20 moves away from the aerial image 10.
When the person 20 stands still, a moving direction detected before the person 20 comes to stand still may be used. The moving direction may be a direction predicted through data processing.
The image formation control part 62 has information (three-dimensional) on the space where the aerial image 10 is formed and information (two-dimensional) on the position of the person 20.
The information on the position where the aerial image 10 is formed may be estimated based on a control history accumulated from an initial position, estimated through communication with the aerial image forming apparatus 31, or provided from other sensors.
The image formation control part 62 of this exemplary embodiment performs control so as to move the position where the aerial image 10 is formed based on the position or the moving direction of the person 20. In the case of this exemplary embodiment, examples of the movement to be used herein include a linear movement, a movement by rotation, a combination of linear movements, a combination of movements by rotation, and a combination of a linear movement and a movement by rotation.
First, the image formation control part 62 determines whether a person has been detected (Step 1).
When the result of Step 1 is NO, the image formation control part 62 repeats the determination until a person is detected.
When the result of Step 1 is YES, the image formation control part 62 identifies the position of the person (Step 2). The position of the person may be identified as coordinates in the space, as a position where the position detecting sensor 33 that has detected the person is attached, or as any one of plural ranges that are the units of detection.
Next, the image formation control part 62 identifies a moving direction. based on information on the identified position of the person (Step 3).
The identification need not be precise identification.
Then, the image formation control part 62 changes the orientation or the contents of an aerial image based on the identified moving direction (Step 4).
For example, the moving direction and the moving distance of the aerial image are determined based on a relationship between the position where the aerial image is formed and the position of the person or a recommended distance for recognition. When the aerial image is a three -dimensional image, the thickness of the aerial image is also taken into consideration.
Examples of the movement of the aerial image include translation and rotation. In those movements, the dimensions of the aerial image are maintained. The translation is a linear movement to be executed without changing the inclination of a display surface before and after the movement. The rotation is a movement involving rotation about a predetermined imaginary axis.
For example, when the aerial image is formed by the method illustrated in
When the aerial image 10 is formed by the method illustrated in
When the aerial image 10 is formed by the method illustrated in
When the aerial image 10 is formed by the method illustrated in
Description is given of a case in which the person 20 approaches the aerial image 10.
The direction 1 is a direction that is defined counterclockwise at 45° with respect to the direction 2. The direction 3 is a direction that is defined clockwise at 45° with respect to the direction 2.
Even if the person 20 moves in any direction, the aerial image 10 is formed so as to face the person 20. Therefore, the visibility of the aerial image 10 for the person 20 increases compared with the case in which the position of the aerial ire age 10 is fixed. In other words, the decrease in the visibility is avoided.
The direction 4 is opposite the direction 2. Therefore, when the person 20 approaches the aerial image 10 in the direction 4, the front side is switched from that in the case in which the person 20 approaches the aerial image 10 in the direction 2. Thus, the person 20 may recognize the aerial image 10 in a proper orientation irrespective of the direction in which the person 20 approaches the aerial image 10.
Description is given of a case in which the person 20 passes by the front of the aerial image 10.
In this movement example, the orientation of the front side of the aerial image 10 (direction of the normal) is caused to follow the movement of the person 20, thereby increasing the visibility of the aerial image 10 for the person 20. Specifically, the orientation of the front side of the aerial image 10 is rotated about an imaginary rotation axis.
In this exemplary embodiment, a line passing through the midpoints of the upper and lower sides that are short sides of the aerial image 10 is defined as the rotation axis. That is, the aerial image 10 is rotated in an XY plane.
Therefore, the aerial image 10 is recognized in a state in which the aerial image 10 faces the person 20 at the position of the person 20 at the time T1, the position of the person 20 at the time T2, and the position of the person 20 at the time T3. Thus, the person 20 recognizes the aerial image 10 easily during the movement.
During the rotation about the rotation axis, the contents of the aerial image 10 may be changed but may be left unchanged, In the example of
For example, an aerial image 10 that reads “AAAA/AAAA/AAAA/AAAA” (“/” means a line break; the same applies hereinafter) as its contents is recognized at the position of the time T1. An aerial image 10 that reads “BBBB/BBBB/BBBB/BBBB” as its contents is recognized at the position of the time T2. An aerial image 10 that reads “CCCC/CCCC/CCCC/CCCC” as its contents is recognized at the position of the time T3.
The display contents are changed at certain timings. By changing the display contents of the aerial image 10 in accordance with the movement of the person 20, various representations may be achieved.
In
In this exemplary embodiment, description is given of an operation of an image control apparatus 32B when plural persons 20A to 20C are located around the aerial image 10. The persons 20A to 20C illustrated in
The aerial image forming system 1B of this exemplary embodiment includes the aerial image forming apparatus 31 that forms the aerial image 10 in the air, the image control apparatus 32B that controls the aerial image forming apparatus 31, and the position detecting sensor 33 that detects the position of the person 20.
In
The image control apparatus 32B of this exemplary embodiment has the hardware configuration illustrated in
In
The functional configuration illustrated in
This exemplary embodiment is different from the first exemplary embodiment in that a target person identifying part 64 is arranged between the position detecting part 60 and the moving direction detecting part 61. In other respects, this exemplary embodiment is in common with the first exemplary embodiment.
The target person identifying part 64 executes processing of identifying a target person for detection of the moving direction out of the plural detected persons 20A to 20C. In the case of this exemplary embodiment, the target person identifying part 64 identifies, as the target person, one of the plural detected persons who is closer to the aerial image 10 than any other persons. In the example of
When plural target persons are present, the target person identifying part 64 determines one of the plural target persons in accordance with a predetermined rule.
For example, when one of the plural target persons is approaching the aerial image 10 but the others are moving away from the aerial image 10, the target person identifying part 64 selects the target person who is approaching the aerial image 10. This is because a person who approaches the aerial image 10 empirically has a greater interest in the aerial image 10 than a person who moves away from the aerial image 10.
For example, when an image capturing camera may be used, a higher priority is given to a person who turns his or her face to the aerial image 10 out of the target persons. This is because the aerial image 10 is controlled for the purpose of increasing the visibility and therefore the aerial image 10 need not be oriented to a person who does not look at the aerial image 10.
Even if a person closer to the aerial image 10 is detected, the target person need not be switched promptly. This is because the visibility for a person who looking at the aerial image 10 may decrease when the target person is switched, for example, before the displaying of advertisement or guidance of a predetermined length of time (for example, 15 seconds) is terminated.
The target person identifying part 64 may be arranged between the moving direction detecting part 61 and the image formation control part 62. In this case, the target person identifying part 64 identifies the target person based on information on the detected positions and the detected moving directions of plural persons.
First, the image formation control part 62 determines whether persons have been detected (Step 11).
When the result of Step 11 is NO, the image formation control part 62 repeats the determination until persons are detected.
When the result of Step 11 is YES, the image formation control part 62 identifies the positions of the persons (Step 12).
Next, the image formation control part 62 identifies a person closer to an aerial image than any other persons (Step 13). When the number of detected persons is one, this processing is not necessary.
Then, the image formation control part 62 identifies a moving direction based on information on the identified position of the person (Step 14).
Then, the tag formation control part 62 changes the orientation or the contents of the aerial image based on the identified moving direction (Step 15).
In
In this exemplary embodiment, description is given of a case in which the control for the orientation or the contents of the aerial image 10 is changed based on whether the detected person 20 is located within or out of a range 34 set around the aerial image 10.
In the case of
In the case of
The aerial image forming system IC of this exemplary embodiment includes the aerial image forming apparatus 31 that forms the aerial image 10 in the air, an image control apparatus 32C that controls the aerial image forming apparatus 31, and the position detecting sensor 33 that detects the position of the person 20.
Information on the range 34 set in advance is stored in the image control apparatus 32C of this exemplary embodiment.
The image control apparatus 32C of this exemplary embodiment also has the hardware configuration illustrated in
In
The functional configuration illustrated in
This exemplary embodiment is different from the first exemplary embodiment in that a range condition determining part 65 is arranged between the position detecting part 60 and the moving direction detecting part 61. In other respects, this exemplary embodiment is in common with the first exemplary embodiment.
The range condition determining part 65 executes processing of determining whether the detected position of the person falls within the range 34 set in advance (see
The range condition determining part 65 may be arranged between the moving direction detecting part 61 and the image formation control part 62.
First, the image formation control part 62 determines whether a person has been detected (Step 21).
When the result of Step 21 is NO, the image formation control part 62 repeats the determination until a person is detected.
When the result of Step 21 is YES, the image formation control part 62 identifies the position of the person (Step 22).
Next, the image formation control part 62 determines whether the identified position of the person falls within the range 34 (see
When the result of Step 23 is NO, the image formation control part 62 terminates the series of processing operations without executing subsequent processing operations.
When the result of Step 23 is YES, the image formation control part 62 identifies a moving direction based on information on the identified position of the person (Step 24).
Then, the image formation control part 62 changes the orientation or the contents of an aerial image based on the identified moving direction (Step 25).
In the case of this example, the range 34 has an elliptical shape and is wide in the direction to the person 20A and narrow in the direction to the person 20C with respect to the display surface of the aerial image 10. Therefore, the aerial image 10 is formed so as to face the person 20A even though the person 20C is closer to the aerial image 10.
In
In this exemplary embodiment, description is given of a case in which two aerial images 10A and 10B are formed by using two aerial image forming apparatuses 311 and 312.
In
The aerial image forming system 1D of this exemplary embodiment includes the aerial image forming apparatus 311 that forms the aerial image 10A in the air, the aerial image forming apparatus 312 that forms the aerial image 10B in the air, an image control apparatus 32D that controls the aerial image forming apparatuses 311 and 312, and the position detecting sensor 33 that detects the positions of the persons 20A and 20B.
The image control apparatus 32D of this exemplary embodiment also has the hardware configuration illustrated in
In
The functional configuration illustrated in
The mage control apparatus 32D according to this exemplary embodiment functions as the position detecting part 60, target person identifying parts 64A and 64B, moving direction detecting parts 61A and 61B, and image formation control parts 62A and 62B.
The target person identifying part 64A, the moving direction detecting part 61A, and the image formation control part 62A are functions for the aerial image 10A. The target person identifying part 64B, the moving direction detecting part 61B, and the image formation control part 62B are functions for the aerial image 10B.
The target person identifying part 64A and the target person identifying part 64B exchange information on identified target persons with each other to share the information. When the number of persons detected by the position detecting part 60 is one, the target person for the aerial image 10A is identical to the target person for the aerial image 10B.
When the number of persons detected by the position detecting part 60 is two or more, different persons are identified as the target person for the aerial image 10A and the target person for the aerial image 10B.
Even if the number of persons detected by the position detecting part 60 is two or more, the same person may be identified as the target person for the aerial image 10A and the target person for the aerial image 10B. Examples of this case include a case in which one person directs his or her line of sight to the aerial images 10A and 10B.
First, the image formation control parts 62A and 62B determine whether persons have been detected (Step 31).
When the result of Step 31 is NO, the image formation control parts 62A and 62B repeat the determination until persons are detected.
When the result of Step 31 is YES, the image formation control parts 62A and 62B identify the positions of the persons (Step 32).
Next, the image formation control parts 62A and 62B identify a person to be associated with the aerial image 10A and a person to be associated with the aerial image 10B (Step 33). As in the case of the second exemplary embodiment, a person closer to the aerial image than any other persons may be identified as the target person. Alternatively, a person who satisfies a predetermined condition may be identified as the target person. When the number of detected persons is one, this processing is not necessary.
Then, the image formation control parts 62A and 62B identify moving directions of the identified persons (Step 34).
Then, the image formation control parts 62A and 62B change the orientations or the contents of the aerial images 10A and 10B based on the identified moving directions (Step 35).
In the example of
When the person 20A and the person 20B are located so as to face each other, the aerial image 10A and the aerial image 10B are also med so as to face each other.
Depending on the distance between the aerial image 10A and the aerial image 10B or the display contents thereof, the visibility may decrease because one image overlaps the other image.
For example, when the aerial images 10A and 10B are viewed from the position of the person 20A, the person 20A recognizes that the contents of the aerial image 10B located on a background side overlap the contents of the aerial image 10A located on a near side. For example, when the aerial images 10A and 10B are viewed from the position of the person 20B, the person 20B recognizes that the contents of the aerial image 10A located on a background side overlap the contents of the aerial image 10B located on a near side.
Any image may be used as the aerial image 10C as long as the visibility of each of the aerial image 10A and the aerial image 10B is increased by forming the aerial image 10C. For example, an image having a uniform color or pattern in its entirety is used as the aerial image 10C. Any color may be used as long as the visibility of the aerial image 10A or 10B located on the near side is increased. For example, it is desirable to use a color having a complementary (opposite) relationship with a color tone that is used for displaying the aerial images 10A and 10B.
An image for increasing the contrast of each of the aerial images 10A and 10B may be used as the aerial image 10C. As the image for increasing the contrast, it is desirable to use, for example, an image in a color tone having a complementary (opposite) relationship with the color tone of each of the aerial images 10A and 10B.
By arranging the aerial image 10C, the visibility of each of the aerial images 10A and 10B is improved.
Since the dimensions of the aerial image 10C are larger than the dimensions of the aerial images 10A and 10B, a visual effect analogous to a frame is attained, thereby increasing the visibility of each of the aerial images 10A and 10B.
The example illustrated in
The example illustrated in
In
In this exemplary embodiment, description is given of a case in which the display contents are changed in accordance with the movement of the person 20 when three aerial images 10A to 10C are arranged.
This exemplary embodiment is an applied example of the control described in each of the first to third exemplary embodiments. For example, the display contents of the aerial images 10A to 10C are changed as in Step 4 (see
In the example illustrated in
In the case of
In
In
The contents of the aerial image 10C are the same as those in its initial state but may be changed in accordance with the contents of the aerial image 10B.
In
As described above, the displaying of the aerial image 10B is changed from “AAAA/AAAA/AAAA/AAAA” to “BBBB/BBBB/BBBB/BBBB” along with the movement of the person 20 and the displaying of the aerial image 10C is changed from “AAAA/AAAA/AAAA/AAAA” to “CCCC CCCC/CCCC/CCCC” along with the movement of the person 20.
In other words, the aerial image forming system 1B performs control so as to sequentially increase the visibilities of the aerial images 10A to 10C to be recognized along with the movement of the person 20.
The contents to be displayed in the aerial images 10A to 10C are not limited to the still image.
The symbol S represents a start point of movement and the symbol E represents an end point of movement. The symbol P1 represents a boundary between the aerial image 10A and the aerial image 10B and the symbol P2 represents a boundary between the aerial image 10B and the aerial image 10C.
The example illustrated in
The example illustrated in
The example illustrated in
Also when the moving image is displayed, it is desirable to control the brightness levels of the aerial images so as to increase the visibility of the aerial image that faces the person 20.
The control in the example illustrated in
In this exemplary embodiment, description is given of a case in which a function of receiving an output instruction for the aerial image is added to each of the aerial image forming systems described above.
In
The aerial image forming system 1F includes the aerial image forming apparatus 31 that forms the aerial image 10 in the air, an image control apparatus 32F that controls the aerial image forming apparatus 31, the position detecting sensor 33 that detects the position of the person 20, a three-dimensional object forming apparatus 35, and an image forming apparatus 36.
The image control apparatus 32F has the hardware configuration illustrated in
The three-dimensional object forming apparatus 35 is an apparatus that forms a three-dimensional object by a method such as stereolithography that involves gradually curing a liquid resin by radiating an ultraviolet ray or the like, fused deposition modeling (FDM) that involves gradually depositing a fused resin, or powder bed binding that involves jetting an adhesive to a powder resin.
The image forming apparatus 36 is an apparatus that forms an image on a recording material such as paper. Examples of the image forming apparatus 36 include a printer that prints an image on paper by a laser or ink jet system.
In
The functional configuration illustrated in
The image control apparatus 32F according to this exemplary embodiment functions as the position detecting part 60, the moving direction detecting part 61, the image formation control part 62, an output instruction receiving part 66 that receives an output instruction for the aerial image, a target recognizing part 67 that recognizes the type of the aerial image subjected to the output instruction, and an output control part 68 that controls an output operation based on a recognition result.
Of those functions, the output instruction receiving part 66, the target recognizing part 67, and the output control part 68 are functions unique to this exemplary embodiment.
The output instruction receiving part 66 is a functional part that receives an output instruction for the aerial image 10 (see
The target recognizing part 67 is a functional part that executes processing of recognizing the type of the aerial image 10 to be output. In this exemplary embodiment, three types that are a document, a three-dimensional object, and a type that does not correspond to the document or the three-dimensional object (that is, other object) are assumed as the types of the aerial image 10. With the type of the aerial image 10, the output format may roughly be identified.
For example, in a case of a document defined by two -dimensional information, there is a high probability that the document may be output as an electronic file or printed on paper.
For example, in a case of a three-dimensional object defined by three-dimensional information, there is a high probability that the three-dimensional object may be formed by three-dimensional modeling or the outer peripheral surfaces in specific directions may sequentially be printed on paper.
The type may be recognized by focusing on a form recognized by the person 20 or by focusing on a data structure that is used for forming the aerial image 10. In the latter case, for example, the type is recognized as a three-dimensional object when the aerial image 10 is recognized as a two-dimensional image but the corresponding data is three-dimensional data.
Examples of the three-dimensional data include data conforming to Standard Triangulated Language (STL) in which a three-dimensional shape is represented as an aggregate of triangles, data in which a three-dimensional shape is represented as an aggregate of voxels, and computer aided design (CAD) data.
The output control part 68 is a functional part that identifies an output format based on a recognition result or an additional instruction from the person and controls an output operation that uses the identified format.
The output instruction receiving part 66 (see
When the result of Step 41 is NO, the output instruction receiving part 66 terminates the processing. The output instruction receiving part 66 may repeat the determination until the result becomes YES.
When the result of Step 41 is YES, the target recognizing part 67 determines whether an aerial image shows a document (Step 42). The target recognizing part 67 acquires information on data that is used for forming the aerial image through communication with the aerial image forming apparatus 31 (see
For example, when two-dimensional data is used for forming the aerial image, the target recognizing part 67 recognizes the aerial image as a document. That is, the result of Step 42 is YES.
When the result of Step 42 is YES, the target recognizing part 67 displays a confirmation screen for the document (Step 43). In the case of this exemplary embodiment, the confirmation screen is formed as an aerial image but may be displayed on a display device provided in the information processing apparatus.
When the aerial image 10 shows the document, candidates are displayed on a confirmation screen W1. That is, two items “OUTPUT AS ELECTRONIC FILE” and “PRINT ON PAPER” are displayed as selection candidates. Various methods are conceivable to select a candidate. For example, an area where the candidate is displayed is selected with a finger or hand.
When the item “OUTPUT AS ELECTRONIC FILE” is selected, the target recognizing part 67 gives an instruction to output the document as an electronic file 100. The electronic file 100 may be generated by the image control apparatus 32F (see
When the item “PRINT ON PAPER” is selected, the target recognizing part 67 gives an instruction to print the image on paper 101.
When the output format is set in advance, the target recognizing part 67 may give an instruction to output the electronic file 100 or print the image on the paper 101 without displaying the confirmation screen W1.
When a desired candidate is not present in the confirmation screen W1, the target recognizing' part 67 displays other candidates through another confirmation screen W2. In
Description is given again with reference to
When an instruction is received on the confirmation screen displayed in Step 43, the output control part 68 gives an instruction to execute an output operation (Step 44).
When the result of Step 42 is NO, the target recognizing part 67 determines whether the aerial image shows a three-dimensional object (Step 45).
When the result of Step 45 is YES, the target recognizing part 67 displays a confirmation screen for the three-dimensional object (Step 46).
When the aerial image 10 shows the three-dimensional object, text for confirming whether to output the three -dimensional object is displayed on a confirmation screen W3.
When “YES” is selected, the target recognizing part 67 gives an instruction to form a three-dimensional object 110. That is, the operation proceeds to the processing of Step 44 (see
Description is given again with reference to
When an instruction is received on the confirmation screen displayed in Step 46, the output control part 68 gives an instruction to execute an output operation (Step 44).
When the result of Step 45 is NO, the target recognizing part displays a confirmation screen for other objects (Step 47).
For example, the other object is an object having two -dimensional data and three-dimensional data mixed in the aerial image 10.
When the aerial image 10 is recognizable neither as a document nor as a three-dimensional object, candidates are displayed on a confirmation screen W5. That is, three items “OUTPUT AS ELECTRONIC FILE”, “PRINT ON PAPER”, and “OUTPUT AS THREE-DIMENSIONAL OBJECT” are displayed as selection candidates.
Description is given again with reference to
When an instruction is received on the confirmation screen displayed in Step 47, the output control part 68 gives an instruction to execute an output operation (Step 44).
When the printing without the aerial image 10C is selected, images corresponding to the aerial image 10A and the aerial image 10B are printed on two sheets of paper 101.
When the printing with the aerial image 10C is selected, in the example of
The technology according to this exemplary embodiment is summarized as a recognition unit that recognizes the type of an aerial image formed in the air and an identification unit that identifies an output format of the aerial image based on the recognized type.
The target recognizing part 67 described above (see FIG. 35) is an example of the recognition unit and the identification unit.
By using this technology, an output operation that uses the format based on the type of the aerial image formed in the sir is achieved easily. The type of the aerial image may be recognized based on a form recognized in the air or based on a data structure that is used for forming the aerial image.
The first to fifth exemplary embodiments described above are directed to the case in which the aerial image 10 is only formed into a planar shape. As described in the sixth exemplary embodiment, the first to fifth exemplary embodiments are also applicable to the case in which the aerial image 10 is formed as a three-dimensional image.
The foregoing description of the exemplary embodiments of the present invention has been provided for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations will be apparent to practitioners skilled in the art. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, thereby enabling others skilled in the art to understand the invention for various embodiments and with the various modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the following claims and their equivalents.
Number | Date | Country | Kind |
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2018-009007 | Jan 2018 | JP | national |