JP2007181153A - Mobile terminal, and irradiation range instruction method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mobile terminal and irradiation range instruction method which enable a user to easily recognize a communicable range of invisible radio signals such as infrared light invisible for the eyes of the user. <P>SOLUTION: A mobile terminal is equipped with an invisible radio signal irradiation section irradiating an invisible radio signal and a visible light irradiation section which irradiates visible light and is provided opposite from the invisible radio signal irradiation section with respect to a direction in which the invisible radio signal irradiation section irradiates an invisible radio signal. An optical path for visible light irradiated by the visible light irradiation section is provided in the vicinity of the invisible radio signal irradiation section viewing from the direction where the invisible radio signal irradiation section irradiates an invisible radio signal. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a portable terminal and an irradiation range instruction method, and more particularly, to a portable terminal and an irradiation range instruction method related to the portable terminal that allow a user to grasp a communication range by an invisible wireless signal such as infrared rays.

IrDA (Infrared Data Association) is an industry standardization organization that develops technical specifications for short-distance data communication using infrared rays, and the infrared communication protocol defined by the association is also called IrDA. In addition, there is a protocol called IrSimple (registered trademark) that further increases the efficiency of the IrDA protocol and increases the data transfer speed, and is standardized by the industry standardization organization IrDA.
When data communication is performed using the IrDA method or the IrSimple (registered trademark) method, there is a problem of a directivity angle. In the IrDA system, a so-called half-duplex communication system in which transmission and reception are alternately performed with a time shift is adopted. Further, in the IrDA system, in order to realize communication that suppresses interference with other infrared communication systems and the influence of external light, the communication distance is 0 to 1 m, the light emitting side directivity angle is ± 15 degrees to ± 30 degrees, The directivity angle on the side is defined as ± 15 degrees.

For this reason, in data communication using the IrDA method, information devices must be installed almost face-to-face, and care must be taken so that the direction of one information device does not tilt significantly during communication.
Therefore, as a technique for improving the above inconvenience, there is known a technique for aligning information equipment when performing data communication using infrared communication by irradiating visible light such as laser light.

For example, Patent Document 1 discloses a technique for causing infrared light and visible light emitted from separate light emitting elements to travel on the same optical path using a mirror that transmits infrared light and reflects visible light. ing. When visible light enters the infrared signal light as noise, an optical filter that blocks visible light is inserted, or the visible light source is cut off during signal transmission.
Patent Document 1 discloses a technique in which two visible light beams are moved in parallel on both sides of an infrared light beam by disposing two visible light light emitting devices with an infrared light emitting device interposed therebetween. Is disclosed.

  Further, in Patent Document 2, the position of the transmitter is adjusted so that the laser light emitted from the transmitter irradiates the infrared light receiving element of the receiver, and after the adjustment, the infrared light emitting element is stopped after the laser emission is stopped in the transmitter. A technique for transmitting an infrared signal from is disclosed.

There is also a desire to know what communication speed is currently being used. In response to this desire, for example, in Patent Document 3, a moving image is displayed in the communication state display area of the display, and the moving image is displayed at one end of the communication state display area according to the communication speed (data reception state and data transmission state). A technique is disclosed that moves from one end to the other, or from the other end to the other end, and is displayed in a different color from the background, and is displayed in a moving speed or color according to the communication speed or communication charge.
JP 62-97438 A Japanese Patent Laid-Open No. 2001-244891 Japanese Patent Laid-Open No. 11-205484

  In the techniques described in Patent Document 1 and Patent Document 2 described above, the laser light irradiated for alignment only forms a projected pattern consisting of one point, two points, or one small region. Absent. The user must perform alignment by relying on a small projection pattern formed by the laser beam. However, it is expected that the reach range of infrared light defined by the transmission directivity angle of infrared light is sufficiently wider than the range indicated by these small projection patterns. If alignment is performed after the reach of infrared light is known, alignment can be performed only by roughly moving the transmitter or receiver.

  In the technique described in Patent Document 3 described above, the user views the communication speed on the screen. However, when performing transmission while performing alignment, the user is watching the vicinity of the alignment target (for example, the infrared light receiving unit of the receiver), not the screen of the transmitter or the screen of the receiver. . Therefore, it is necessary to present information such as the communication speed in the vicinity of an object to be aligned (for example, an infrared light receiving unit of a receiver).

  The present invention has been made in view of the above circumstances, and an object of the present invention is to enable a user to easily grasp a communicable range using an invisible wireless signal such as infrared rays that cannot be seen by the user. It is to provide a terminal and an irradiation range instruction method.

  The portable terminal of the present invention is made to solve the above-described problem, and an invisible wireless signal irradiating unit that irradiates an invisible wireless signal, and a visible light irradiating unit that irradiates visible light that forms a projection pattern at an irradiation destination. And the boundary of the irradiation range at the irradiation destination of the invisible wireless signal is indicated by the projection pattern.

  In the mobile terminal of the present invention, the visible light irradiation unit narrows the visible light irradiation range at the irradiation destination to be smaller than the irradiation range of the invisible wireless signal at the irradiation destination.

  In addition, the portable terminal of the present invention is provided with an invisible wireless signal irradiating unit that irradiates an invisible wireless signal, and a direction opposite to the direction in which the invisible wireless signal irradiating unit irradiates the invisible wireless signal than the invisible wireless signal irradiating unit. A visible light irradiating unit for irradiating visible light, and the visible light irradiating unit irradiates a peripheral part of the invisible wireless signal irradiating unit as viewed from a direction in which the invisible wireless signal irradiating unit emits an invisible wireless signal. An optical path for visible light is provided.

  In the portable terminal of the present invention, the optical path is at least an optical path in the vertical direction or the horizontal direction in a front view from the irradiation direction of the invisible wireless signal.

  In the portable terminal according to the present invention, the optical path is at least an optical path in the vertical and horizontal directions when viewed from the irradiation direction of the invisible wireless signal.

  In the mobile terminal of the present invention, the front view from the irradiation direction of the invisible wireless signal is an optical path that irradiates the boundary of the irradiation range of the invisible wireless signal or the irradiation range.

  In addition, the portable terminal of the present invention includes an operation unit that receives the first or second instruction, a transmission processing unit that transmits data using the invisible wireless signal irradiation unit, and the operation unit receives the first instruction. When receiving, the visible light irradiation unit starts irradiation of visible light, and when the operation unit receives a second instruction, starts transmission of data by the transmission processing unit, and the transmission processing unit A control unit that terminates the irradiation of visible light by the visible light irradiation unit when transmission is completed.

  Further, in the portable terminal of the present invention, the control unit changes the irradiation time per unit time of the visible light irradiated by the visible light irradiation unit according to whether or not the operation unit receives the second instruction. Let

  In the mobile terminal of the present invention, the control unit changes the irradiation time per unit time of the visible light irradiated by the visible light irradiation unit according to the speed at which the transmission processing unit transmits data.

  In addition, the irradiation range instruction method of the present invention irradiates an invisible wireless signal by an invisible wireless signal irradiation unit, and irradiates visible light that forms a projection pattern on an irradiation destination by the visible light irradiation unit, so that the projection pattern The boundary of the irradiation range in the irradiation destination of an invisible wireless signal is shown.

In the present invention, the boundary of the irradiation range of the invisible wireless signal irradiated by the invisible wireless signal irradiation unit is indicated by the projection pattern formed by the visible light irradiated by the visible light irradiation unit.
As a result, the user can know the boundary of the irradiation range of the invisible wireless signal such as invisible infrared rays by the visible light projection pattern such as the visible laser beam, so the user can use the portable terminal. Wireless communication can be performed reliably.

(First embodiment)
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
The information processing system illustrated in FIG. 1A includes a mobile terminal 10 and an image display device 20. The mobile terminal 10 transmits the image displayed on the screen 14 to the image display device 20 using infrared communication and displays the image on the screen 21.
In the present embodiment, the mobile terminal 10 is a mobile phone, and the image display device 20 is a television receiver. As the portable terminal 10, a PDA (Personal Digital Assistance), a PHS (Personal Handyphone System), a PC (Personal Computer), a remote control of the television 106, or the like may be used. Further, as the image display device 20, a projector or a PC may be used.

In the present embodiment, an image is used as data to be transmitted from the mobile terminal 10 to the image display device 20, but sound such as music, a moving image, or the like may be used. In the case of sound, the image display device 20 uses a sound output device. In this case, a sound output device (not shown) built in the image display device 20 may be used as the sound output device, or otherwise. Independent audio output devices may be used. Other arbitrary data may be used as data transmitted from the portable terminal 10 to the image display device 20.
In the present embodiment, the mobile terminal 10 transmits data from the light emitting unit 15 to the image display device 20 using infrared communication. Infrared rays transmitted from the portable terminal 10 to the image display device 20 are indicated by arrows 12 in FIG. Infrared light is invisible, so it is not visible to the human eye. Infrared rays are electromagnetic waves having a wavelength of 780 nm to 1000000 nm.

Infrared communication has a directional angle. Unless the light emitting unit 15 of the portable terminal 10 emits light toward the infrared light receiving unit 201 of the image display device 20 so as to fall within an angle of ± 15 degrees, the infrared light receiving unit 201 of the image display device 20 cannot receive light. Therefore, in the present embodiment, the mobile terminal 10 emits a laser beam having a lower output than the light emitting unit 15 and projects the annular projection pattern 11 a on the image display device 20. The range surrounded by the projection pattern 11a coincides with the infrared reachable range emitted by the mobile terminal 10, or is included in the infrared reachable range emitted by the mobile terminal 10. Therefore, if infrared light is emitted from the portable terminal 10 while the portable terminal 10 is held so that the infrared light receiving unit 201 of the image display device 20 is positioned inside the projected pattern 11a of the laser light, the emitted infrared light is displayed as an image. Light can be received by the infrared light receiving unit 201 of the apparatus 20. In FIGS. 1B and 1C, since the infrared light receiving unit 201 is located outside the projection patterns 11 b and 11 c of the laser light, the infrared light receiving unit 201 does not receive the infrared light emitted from the mobile terminal 10. Can not.
On the other hand, in FIGS. 1A and 1D, since the infrared light receiving unit 201 is located inside the projected patterns 11 a and 11 d of the laser light, infrared light emitted from the mobile terminal 10 is transmitted by the infrared light receiving unit 201. It can receive light.

FIG. 2 is a configuration diagram of the light emitting unit 15 having a cylindrical shape of the mobile terminal 10 according to the first embodiment of the present invention. 2A is a cross-sectional view of the light emitting unit 15, and FIG. 2B is a front view of the light emitting unit 15.
The laser beam irradiation unit 102 is attached to the laser beam irradiation unit mounting unit 104 and irradiates the laser beam toward the front. The infrared irradiation unit 101 is attached to an infrared irradiation unit attachment unit 103 that forms a cylindrical pedestal, and irradiates infrared rays toward the front. A laser beam irradiation unit 102 is installed at a position that is a predetermined distance n away from the direction D1 in which the infrared irradiation unit 101 irradiates infrared rays. The predetermined distance n is, for example, a distance that satisfies n = r / tan (15 °) with respect to the radius r of the pedestal of the infrared irradiation unit attachment unit 103. When the radius of the pedestal of the infrared irradiation unit attachment unit 103 is 2.5 mm, the predetermined distance n is about 5 mm. As described above, in the mobile terminal 10 according to the present embodiment, the infrared irradiation unit 101 (invisible wireless signal irradiation unit) that emits infrared rays (invisible wireless signals) and the infrared irradiation unit 101 emits infrared rays more than the infrared irradiation units 101. A laser light irradiation unit 102 (visible light irradiation unit) that is provided in a direction opposite to the direction D1 and emits laser light is provided, and the infrared irradiation unit 101 has a peripheral portion of the infrared irradiation unit 101 when viewed from the direction in which infrared irradiation is performed. An optical path for laser light (visible light) irradiated by the laser light irradiation unit 102 is provided.

As shown in FIG. 2C, the laser beam irradiation unit 102 covers the laser beam output unit 108 that outputs the laser beam and diffuses the laser beam irradiated by the laser beam output unit 108 radially. A hemispherical lens 109 serving as a diffusing unit is provided. Thereby, the laser light irradiated by the laser light irradiation unit 102 is diffused by the hemispherical lens, and is between the infrared irradiation unit mounting unit 103 having a circular cross section and the inner wall of the outer frame 105 having a circular cross section. The light is emitted to the outside of the light emitting unit 15 through the optical path. A part of the laser light irradiated by the laser light irradiation unit 102 is shielded by the infrared irradiation unit attachment unit 103.
A plurality of laser light irradiation units are provided in the laser light irradiation unit mounting unit 104 without using the hemispherical lens described above, and the laser light irradiated by each laser light irradiation unit is separated from the infrared irradiation unit mounting unit 103. A projection pattern may be formed by passing through an optical path between the frame 105 and the light emitted from the light emitting unit 15. Further, the projection pattern is formed by moving the direction of the laser beam irradiated by one laser beam irradiation unit 102 at high speed along the optical path between the infrared irradiation unit mounting unit 103 and the outer frame 105. May be. Specifically, for example, the laser light emitting element (laser light irradiation unit 102) is rotated at high speed along an annular region between the infrared irradiation unit attachment unit 103 and the outer frame 105 in FIG. Thus, the projection pattern of the laser beam may be formed in an annular shape. In addition, with the laser beam irradiation unit 102 fixed, a mirror that reflects the laser beam is provided so that the laser beam passes through the optical path between the infrared irradiation unit mounting unit 103 and the outer frame 105, and the mirror is rotated at high speed. By doing so, the projection pattern of the laser beam may be formed in an annular shape.
In the present embodiment, the laser light irradiation unit 102 irradiates a laser beam that can be visually recognized by humans. However, the laser beam irradiation unit 102 irradiates light within a wavelength range of 400 nm to 700 nm that can be visually recognized by humans. If so, other devices may be used, and the light source of the laser light may not be used.
In the present embodiment, the infrared irradiation unit 101 irradiates infrared rays that cannot be visually recognized by humans. However, if an electromagnetic wave outside the wavelength range of 400 nm to 700 nm that is not visible to humans is irradiated, other You may use the apparatus of.

3A to 3D are diagrams showing an example of a configuration for realizing the light emitting unit 15 according to the first embodiment of the present invention. 3A and 3C are cross-sectional views of a part of the housing including the laser beam irradiation unit 102 and the infrared irradiation unit 101, respectively. FIGS. 3B and 3D are cross-sectional views corresponding to the light emitting section 15 in FIGS. 3A and 3C, respectively.
2 (a) and 2 (b), for the sake of explanation, the infrared irradiation unit mounting unit 103 to which the infrared irradiation unit 101 is mounted is described as floating in the air, but the infrared irradiation unit mounting unit 103 is actually outside. It is fixed with respect to the frame 105.

In FIG. 3A, the infrared irradiation unit attachment unit 103 is supported by a support rod 106 extending from the laser beam irradiation unit 102 in the direction D1. Since the laser beam irradiation unit mounting portion 104 is fixed to the outer frame 105, the infrared irradiation unit mounting unit 103 is also fixed to the outer frame 105. At this time, as shown in FIG. 3B, the support rod 106 is not visible when viewed from the front. Since the shadow by the support rod 106 cannot be formed, the projected pattern 11 can be formed in an annular shape (see FIG. 6A described later).
In FIG.3 (c), the infrared irradiation part attachment part 103 is being fixed by the four support rods 107a-107d extended from the outer frame 105 to the direction perpendicular | vertical with respect to the direction D1.
As shown in FIG. 3D, the projection pattern shielded by the support bars 107a to 107d can be seen when viewed from the front (see FIG. 6D described later).

FIG. 4 is a cross-sectional view showing an example in which laser light and infrared light are respectively emitted from the laser light irradiation unit 102 and the infrared irradiation unit 101 according to the first embodiment of the present invention. In FIG. 4, for convenience of explanation, laser light and infrared light are emitted toward a screen 16 provided in front of the light emitting unit 15.
The infrared rays irradiated from the infrared irradiation unit 101 are irradiated toward the screen 16 within the range of the transmission directivity angle ± 15 ° of the infrared irradiation unit 101. A region through which the irradiated infrared ray passes is indicated by Y. On the other hand, the laser beam irradiated from the laser beam irradiation unit 102 is irradiated toward the screen 16 while being partially shielded by the infrared irradiation unit mounting unit 103 and the outer frame 105. A region through which the irradiated laser beam passes is indicated by X. The boundary between the region X and the region Y is formed when the laser beam irradiated by the laser beam irradiation unit 102 is shielded by the infrared irradiation unit mounting unit 103. Thereby, on the screen 16, a visible projection pattern 11 is formed at the boundary between the region X and the screen 16, thereby determining the infrared reachable range 13 formed at the boundary between the region Y and the screen 16. Can do.

  FIG. 5 is a cross-sectional view showing another example in which laser light and infrared light are respectively emitted from the laser light irradiation unit 102 and the infrared light irradiation unit 101 according to the first embodiment of the present invention. When the transmission directivity angle of the infrared irradiation unit 101 is ± 15 °, the boundary of the region Y spreading in a fan shape of ± 15 ° from the infrared irradiation unit 101 does not necessarily coincide with the boundary of the region X. That is, if the range surrounded by the projection pattern 11 is within the infrared reach range 13 on the screen 16, the infrared light receiving unit 201 of the image display device 20 emits the infrared light from the mobile terminal 10. This is because the infrared rays surely reach the infrared light receiving unit 201 of the image display device 20 by transmitting the infrared rays after confirming that they are inside.

Therefore, in FIG. 5, when the boundary between the region X and the region Y formed when the laser light emitted from the laser light irradiation unit 102 is shielded by the infrared irradiation unit attachment unit 103 is formed, The region Y is a region extending from the laser light irradiation unit 102 in a sector shape of ± 12 °. The sector central angle (± 12 °) is set to be ± 3 ° narrower than the transmission directivity angle (± 15 °) of the infrared irradiation unit 101. In other words, the projection pattern 11 by the laser light irradiated from the laser light irradiation unit 102 through the space between the infrared irradiation unit mounting unit 103 and the outer frame 105 causes the infrared irradiation range on the screen 16 (irradiation destination). A range narrower than the infrared reachable range 13 formed at the boundary with a certain region Y is shown.
Although this setting depends on the arrangement of the infrared irradiation unit attachment unit 103, it is not always necessary to shield the laser beam by the infrared irradiation unit attachment unit 103, and a configuration in which the laser beam is shielded by another member may be used.

In addition, by such a setting, by removing from the region Y the region where the infrared receiving sensitivity is relatively lowered in the vicinity of the boundary with the region X of the region Y extending in a fan shape of ± 15 ° from the infrared irradiation unit 101, Improve the certainty that infrared rays reach the infrared ray receiver 201 of the image display device 20 when transmitting the infrared ray after confirming that the infrared ray receiver 201 of the image display device 20 is inside the projection pattern 11 be able to.
When the directivity angle of the infrared irradiation unit 101 is ± 15 °, an angle in the range of ± 10 ° or more and less than ± 15 ° may be set as the central angle formed by the boundary between the region X and the region Y. desirable. This is because if the narrow angle is set as the central angle, the infrared light reaches the infrared light receiving unit 201 of the image display device 20 even when the infrared light receiving unit 201 of the image display device 20 is outside the projection pattern 11. This is because the pattern 11 does not serve as a mark of a range where infrared communication is possible.

Although the example which has arrange | positioned the infrared irradiation part 101 in front of the laser beam irradiation part 102 was demonstrated using FIGS. 2-5, this is the infrared rays which the portable terminal 10 light-emitted the area | region enclosed by the projection pattern 11 It is merely described as one means for causing the region surrounded by the projected pattern 11 to be included in the infrared reachable range 13 emitted from the mobile terminal 10.
For example, the infrared irradiation unit 101 and the laser beam irradiation unit 102 are arranged side by side, not front and back, and the laser beam irradiation unit 102 emits light so as to project the projection pattern 11 in an annular shape according to the directivity angle of the infrared irradiation unit 101, In addition, the region surrounded by the projection pattern 11 projected in a ring shape matches the infrared reachable range 13 irradiated by the mobile terminal 10 or is surrounded by the projected pattern 11 within the infrared reachable range 13 irradiated by the mobile terminal 10. It is also possible to control the light emission of the laser light irradiation unit 102 so that the region is included.

FIGS. 6A to 6F are diagrams illustrating an example of a projection pattern formed by infrared rays irradiated by the infrared irradiation unit 101 of the mobile terminal 10 according to the first embodiment of the present invention. A circular region 13 in FIGS. 6A to 6F indicates an infrared reachable range 13 irradiated from the infrared irradiation unit 101 of the mobile terminal 10.
FIG. 6A shows a case where the projection pattern 11 has the above-described ring shape. As shown in the figure, the region surrounded by the projection pattern 11 coincides with the infrared reachable range 13 irradiated by the infrared irradiation unit 101 of the mobile terminal 10. In addition, the structure where the area | region enclosed by the projection pattern 11 is contained in the infrared reachable range 13 which the infrared irradiation part 101 irradiated may be sufficient. If at least the infrared reachable range 13 irradiated by the mobile terminal 10 includes a region surrounded by the projected pattern 11, the infrared light receiving unit 201 of the image display device 20 is positioned inside the projected pattern 11 of the laser light. When the mobile terminal 10 is irradiated with infrared light while holding the mobile terminal 10, the irradiated infrared light can be received by the infrared light receiving unit 201 of the image display device 20. Therefore, the mobile terminal 10 is moved so that the infrared light receiving unit 201 of the image display device 20 is positioned inside the laser light projection pattern 11 without overlapping the laser light projection pattern 11.

FIG. 6B shows a case where the projection pattern 11 has a heart-shaped outline. FIG. 6C shows a case where the projection pattern 11 has a rectangular outline. 6B and 6C, the region surrounded by the projection pattern 11 is included in the infrared reachable range 13 irradiated by the infrared light receiving unit 201.
In FIG. 6A, the optical path of the laser beam is formed so as to irradiate the boundary of the infrared irradiation range 13 in a front view from the infrared irradiation direction.
6B and 6C, the optical path of the laser beam is formed to be an optical path for irradiating the irradiation range of the infrared irradiation range 13 in a front view from the infrared irradiation direction.
FIG. 6D shows a case where the projection pattern 11 of the laser beam has an annular contour, and the ring is not continuous and is broken at four locations. FIG. 6E shows a case where the projection pattern 11 of the laser beam is formed so as to be spaced apart at six positions on the circumference. 6D and 6E, the closed region (annular closed region) formed by virtually connecting the discrete projection patterns 11 is included in the infrared reachable range 13 emitted from the mobile terminal 10. .

FIG. 6F shows a case where the projection pattern 11 is formed by two elliptical small regions. If infrared rays are irradiated from the infrared irradiation unit 101 in a state where the portable terminal 10 is held so that the infrared light receiving unit 201 of the image display device 20 is positioned on a line segment connecting the two small regions, the irradiated infrared ray is displayed as an image. Light can be received by the infrared light receiving unit 201 of the apparatus 20. In the state where the portable terminal 10 is held such that the infrared light receiving unit 201 of the image display device 20 is positioned in a region where the line segment is rotated around the midpoint of the line segment connecting the two elliptical small regions. If infrared rays are irradiated from the infrared irradiation unit 101, the irradiated infrared rays can be received by the infrared light receiving unit 201 of the image display device 20. As a result, even when the projection pattern 11 is two elliptical small regions, the infrared light irradiated by the infrared irradiation unit 101 can be received by the infrared light receiving unit 201 of the image display device 20 if the mobile terminal 10 is moved to any position. The user of the mobile terminal 10 can know this.
In FIG. 6 (f), the optical path of the laser beam is formed so as to be an optical path in two directions left and right in the front view from the direction of infrared irradiation. The optical path may be formed so as to be an optical path in the vertical direction, or may be formed so as to be an optical path in the vertical and horizontal directions.
In addition, in order to make the projection pattern 11 into the shape as shown in FIG. 6B to FIG. 6F, a gap between the infrared irradiation unit attachment unit 103 and the outer frame 105 (FIG. 2B). The shape of the optical path as shown in FIG. 6 can be realized by making the shape as shown in FIGS. 6B to 6F.

  FIG. 7 is a block diagram showing the configuration of the mobile terminal 10 according to the first embodiment of the present invention. The mobile terminal 10 includes a mobile terminal operation unit 301, a mobile terminal display unit 302, a display image creation unit 303, a mail transmission processing unit 304, a network communication unit 305, an additional data acquisition processing unit 306, an additional data transmission unit 307, an image operation. Information transmission unit 308, image data transmission unit 309, image data holding unit 310, image data synthesis unit 311, transmission / reception processing unit 312, laser light irradiation instruction unit 313, infrared light reception unit 314, infrared irradiation unit 315, laser light irradiation unit 316 Have

The infrared irradiation unit 315 emits infrared rays for data communication. The infrared light receiving unit 314 receives infrared light for data communication. For data communication, for example, an IrDA method or an IrSimple (registered trademark) method can be used. IrDA is an industry standardization organization that develops technical specifications for performing short-distance data communication using infrared rays, and the infrared communication protocol defined by the organization is also called IrDA. IrSimple is a protocol in which the IrDA protocol is further streamlined to increase the data transfer speed, and is standardized by the industry standardization organization IrDA.
The infrared irradiation unit 315 and the infrared light receiving unit 314 may be realized by one light receiving and emitting element, or the infrared irradiation unit 315 may be realized by a light emitting element and the infrared light receiving unit 314 may be realized by a light receiving element. When the infrared irradiation unit 315 and the infrared light receiving unit 314 are realized as separate elements, the infrared irradiation unit 315 and the infrared light receiving unit 314 are arranged close to each other in the mobile terminal 10.

The laser light irradiation unit 316 irradiates laser light. Here, similarly to the laser pointer, a laser beam that emits visible light in a wavelength range of 400 nm to 700 nm is used.
The transmission / reception processing unit 312 performs a function of performing data communication using the infrared irradiation unit 315 and the infrared light receiving unit 314. That is, the infrared irradiation unit 315, the infrared light receiving unit 314, and the transmission / reception processing unit 312 constitute a communication unit.
The laser beam irradiation instruction unit 313 also instructs the laser beam irradiation unit 316 to perform laser beam irradiation based on an instruction from the transmission / reception processing unit 312. The portable terminal operation unit 301 is a part for inputting a user's instruction, and includes a button, a jog dial, a pen input, and the like. When the mobile terminal 10 is not the mobile terminal 10 but a PC or the like, the mobile terminal 10 includes a mouse, a keyboard, and the like. The mobile terminal display unit 302 is a part that displays information, and is configured by a liquid crystal panel, for example. In the present embodiment, the information to be output is described as an image. For example, when the information to be output is audio, the output information is configured by a speaker that outputs audio.

The image data holding unit 310 holds a file of image data. The display image creation unit 303 displays the image held in the image data holding unit 310 on the portable terminal display unit 302. The image data transmission unit 309 reads image data corresponding to the image displayed by the display image creation unit 303 from the image data holding unit 310 based on an instruction from the mobile terminal operation unit 301, and transmits / receives a transmission / reception processing unit 312 and an infrared irradiation unit. The data is transmitted to an image display device such as a television receiver which is an external device via 315.
The image operation information transmission unit 308 transmits operation information for the image displayed on the image display device 20 input from the portable terminal operation unit 301 to the image display device 20 via the transmission / reception processing unit 312. The operation information for the image displayed on the image display device 20 includes, for example, image rotation, enlargement, reduction, movement, change in color luminance, cropping, cropping, and the like. In addition, when the image is a moving image, there are a still image display by replay, stop, and pause, fast forward, rewind, and the like.

The additional data transmission unit 307 inputs “write” to the image displayed on the image display device 20 input from the portable terminal operation unit 301 to the image display device 20 via the transmission / reception processing unit 312 and the infrared irradiation unit 315. Send. “Writing” with respect to the image displayed on the image display device 20 is information to be displayed over the image. For example, a mark such as a circle or square, a stamp on which a character or the like is drawn, character information, a balloon in which a character is written, a locus drawn in freehand, or the like corresponds. In the example of actual photographic paper, writing is performed with a pen on a photograph taken on the photographic paper, but information corresponding to the information written with the pen is displayed on the image display device 20. This is referred to as “writing” with respect to the current image.
When the user of the mobile terminal 10 receives an instruction requesting acquisition of an image displayed on the image display device 20 from the mobile terminal operation unit 301, the additional data acquisition processing unit 306 is a transmission / reception processing unit 312; A data request is transmitted to the image display device 20 via the infrared irradiation unit 315. Accordingly, additional data for writing on the image displayed on the image display device 20 is received from the image display device 20 via the infrared light receiving unit 314 and the transmission / reception processing unit 312. When image data based on the image displayed on the image display device 20 is not held, the image data may be received from the image display device 20 via the infrared light receiving unit 314 and the transmission / reception processing unit 312. .

The image data composition unit 311 generates a new image by superimposing additional data on the image data image held by the image data holding unit 310, and the generated image data is stored in the image data holding unit 310. Hold. Superimpose, which is a technique for superimposing and displaying another image on a certain image, can be used for graffiti processing, which is a process of superimposing additional data on image data.
The network communication unit 305 can perform communication via a network. This is constituted by, for example, a network card or a communication module of a mobile phone network. For communication, a medium such as a mobile phone network, a general telephone line, ADSL (Asymmetric Digital Subscriber Line), optical fiber, IEEE (Institute of Electrical and Electronic Engineers) 802.11, Bluetooth (registered trademark), or the like can be used.
The mail transmission processing unit 304 can generate a mail attached with the image data extracted from the image data holding unit 310 based on an instruction from the portable terminal operation unit 301 and transmit the mail to another device via the network communication unit 305. it can.

  FIG. 8 is a block diagram showing an example of the configuration of the image display device 20 according to the first embodiment of the present invention. The image display device 20 includes a large screen display unit 401, a received image data holding unit 402, a display image creating unit 403, a received additional data holding unit 404, an image operation information receiving processing unit 405, an image data receiving processing unit 406, an additional data. Reception processing unit 407, additional data return processing unit 408, first transmission / reception processing unit 409, second transmission / reception processing unit 410, third transmission / reception processing unit 411, first infrared irradiation unit 412, first infrared light receiving unit 413, second infrared light An irradiation unit 414, a second infrared light receiving unit 415, a third infrared irradiation unit 416, and a third infrared light receiving unit 417 are provided.

The first to third infrared irradiation units 412, 414, and 416 irradiate infrared rays for data communication. The first to third infrared light receivers 413, 415, and 417 receive infrared light for data communication. For data communication, for example, the IrDA method or the IrSimple method can be used. The infrared irradiation unit and the infrared light receiving unit may be realized by a single light receiving and emitting element, or may be realized by using the infrared irradiation unit as a light emitting element and the infrared light receiving unit as a light receiving element. When the infrared irradiation unit and the infrared light receiving unit are realized as separate elements, the infrared irradiation unit and the infrared light receiving unit are arranged close to each other.
The first to third transmission / reception processing units 409, 410, and 411 implement data communication using the first to third infrared irradiation units 412, 414, and 416 and the infrared light receiving units 413, 415, and 417, respectively.

Here, the image display device 20 includes three sets of an infrared irradiation unit, an infrared light receiving unit, and a transmission / reception processing unit. In some embodiments to be described later, the roles of the three sets are described separately, but here, it is only necessary to provide one set including an infrared irradiation unit, an infrared light receiving unit, and a transmission / reception processing unit. When describing an embodiment that only needs to have one set, the names of an infrared irradiation unit, an infrared light receiving unit, and a transmission / reception processing unit are used. As the first infrared irradiation unit 412, the first infrared light receiving unit 413, the first transmission / reception processing unit 409, and the second set as the second infrared irradiation unit 414, the second infrared light receiving unit 415, and the second transmission / reception processing unit 410. The names of the third infrared irradiation unit 416, the third infrared light receiving unit 417, and the third transmission / reception processing unit 411 are used as a third set.
The large screen display unit 401 is a part for displaying information, and is configured by a liquid crystal panel, for example. In the present embodiment, output information is described as an image. For example, when the output information is audio, the large screen display unit 401 is configured as a speaker that outputs audio.
The received image data holding unit 402 holds a file of received image data. The reception additional data holding unit 404 holds the received additional data. The received operation information is also stored.

The image data reception processing unit 406 receives image data from the mobile terminal 10 via the first to third transmission / reception processing units 409, 410, and 411, holds the received image data in the received image data holding unit 402, and receives the received image data The display image creation unit 403 is instructed to display an image based on the above.
The image operation information reception processing unit 405 receives operation information from the portable terminal 10 via the first to third transmission / reception processing units 409, 410, and 411, holds the operation information in the reception additional data holding unit 404, and displays the large screen. The display image creation unit 403 is instructed to reflect the received operation information on the image displayed on the unit 401 to be displayed again.
The additional data reception processing unit 407 receives additional data from the plurality of mobile terminals 10 via the first to third transmission / reception processing units 409, 410, and 411, holds the additional data in the reception additional data holding unit 404, and displays a large screen. The display image creation unit 403 is instructed to superimpose the received additional data on the image displayed on the display unit 401.

The additional data reply processing unit 408 receives data requests from the plurality of mobile terminals 10 via the first to third transmission / reception processing units 409, 410, and 411, and the additional data held in the received additional data holding unit 404 Is transmitted to the mobile terminal 10 via the first to third transmission / reception processing units 409, 410, and 411. If it is determined by referring to the data request that the device that transmitted the data request does not have image data based on the image displayed on the large screen display unit 401, the received image data holding unit 402 displays the data request. The image data based on the image is taken out, and the first to third transmission / reception processing units 409, 410, and 411 and the additional data together with the additional data from the first to third infrared irradiation units 412, 414, and 416. You may make it transmit to either.
The display image creating unit 403 reflects the operation information held in the received additional data holding unit 404 on the image based on the image data held in the received image data holding unit 402, and further in the received additional data holding unit 404. An image in which the stored additional information is superimposed is generated and displayed on the large screen display unit 401.

FIG. 9 is a flowchart illustrating an example of a process flow of the mobile terminal 10 according to the first embodiment of the present invention. This flowchart shows a process of transmitting an image from the mobile terminal 10 to the image display device 20.
First, the user of the mobile terminal 10 selects an image by operating the mobile terminal operation unit 301 (step S101). Then, the display image creation unit 303 reads the image selected by the mobile terminal operation unit 301 from the image data holding unit 310 and displays it on the mobile terminal display unit 302 (step S102).

The user of the mobile terminal 10 instructs preparation for transmission using infrared rays by operating the mobile terminal operation unit 301 (step S103). The image data transmission unit 309 reads out image data corresponding to the image displayed on the mobile terminal display unit 302 from the image data holding unit 310 (step S104). The transmission / reception processing unit 312 irradiates the laser beam with the laser beam irradiation unit 316 via the laser beam irradiation instruction unit 313 (step S105). The user of the mobile terminal 10 instructs the start of image data transmission by operating the mobile terminal operation unit 301 (step S106). The transmission / reception processing unit 312 transmits image data to the image display device 20 by irradiating infrared rays from the infrared irradiation unit 315 (step S107). When the image data transmission unit 309 has finished transmitting the image data, the laser beam irradiation unit 316 ends the laser beam irradiation via the transmission / reception control unit 312 and the laser beam irradiation instruction unit 313 (step S108). .
In the mobile terminal 10 according to the present embodiment, a first instruction for irradiating laser light is received in step S105, and a second instruction for starting infrared communication is received in step S106. The mobile terminal operation unit 301 (operation unit). Accept by. In step S107, data is transmitted by the transmission / reception processing unit 312 (transmission processing unit) using the infrared irradiation unit 315. That is, when the mobile terminal operation unit 301 receives the first instruction, the laser light irradiation unit 316 starts laser beam irradiation, and when the mobile terminal operation unit 301 receives the second instruction, the transmission / reception processing unit 312. When the transmission / reception processing unit 312 ends the data transmission, the laser beam irradiation instruction unit 313 (control unit) ends the laser beam irradiation by the laser beam irradiation unit 316.

The laser beam irradiation unit 316 does not necessarily have to continuously irradiate the laser beam, but intermittently irradiates (for example, irradiates for 0.2 seconds every unit time of 1 second and pauses for 0.8 seconds). May be. By irradiating intermittently, power consumption can be reduced.
Further, various types of information may be notified by blinking of the projected pattern 11 generated by intermittently irradiating laser light. For example, the unit time of the laser light emitted by the laser light irradiation unit 316 depending on whether the portable terminal operation unit 301 has received an instruction to start infrared communication (second instruction) by the laser light irradiation instruction unit 313 Change the per irradiation time. Thereby, if the projection pattern 11 is blinking, the user can know that infrared communication is normally performed.

  Further, after starting the emission of the laser beam in step S105 in FIG. 9, the laser beam is continuously irradiated, and after the user instructs the start of transmission in step S106, the laser beam is irradiated intermittently. Accordingly, when the user moves the mobile terminal 10 so that the infrared light receiving unit 201 is positioned inside the projection pattern 11, the projection pattern 11 does not blink so that the projection pattern 11 can be clearly seen, and the user can The projection pattern 11 blinks in order to save power consumption during infrared communication that holds the mobile terminal 10 so that the infrared light receiving unit 201 does not come off from the inside of the computer 11. It should be noted that the laser light is emitted intermittently even after the laser light emission is started in step S105 in FIG. 9 and also after the user instructs the start of transmission in step S106, and the former irradiation interval. May be made narrower than the latter irradiation sensation. For example, the former may be irradiated for 2 seconds every 3 seconds, and the latter may be irradiated for 0.5 seconds every 3 seconds. Thereby, there can exist the same effect as the above.

Furthermore, the laser beam irradiation unit 316 may change the blinking interval of the laser beam according to the communication flow rate of infrared communication. For example, the laser light irradiation may be performed such that the irradiation is stopped for 0.2 seconds every time transmission of 100 Kbytes of data is completed. For example, the laser light irradiation instruction unit 313 changes the irradiation time per unit time of the laser light irradiated by the laser light irradiation unit 316 according to the speed at which the transmission / reception processing unit 312 transmits data. Thereby, the user can visually confirm the speed of infrared communication. Further, the end of data communication of infrared communication may be notified using blinking.
During infrared communication, in order to hold the mobile terminal 10 so that the infrared light receiving unit 201 is not detached from the inside of the projection pattern 11, the user is gazing at the infrared light receiving unit 201 and the projection pattern 11. For this reason, notifying the user of various types of information by blinking of the projection pattern 11 caused by intermittently irradiating the laser beam means, for example, when displaying various types of information on the mobile terminal display unit 302 of the mobile terminal 10. In comparison, it is effective to attract the user's attention.

FIGS. 10A to 10C are diagrams illustrating an example of an operation example when image data is transmitted from the portable terminal 10 to the image display device 20 according to the first embodiment of the present invention.
FIG. 10D is a diagram illustrating an example of the configuration of the lower housing 30 (see FIG. 10A) of the mobile terminal 10. The lower housing 30 has a “1” key 31, a “2” key 32, a “3” key 33, a “4” key 34, a “5” key 35, a “6” key 36, a “7” key 37, “ An “8” key 38, a “9” key 39, a “0” key 40, a “*” key 41, a “#” key 42, a cross key 43, an enter key 44, and the like are provided.
When the user of the mobile terminal 10 operates the mobile terminal operation unit 301 to start an application for image display and infrared communication, an image title as shown in FIG. 10A is displayed on the screen 14. The user selects image data to be transmitted to the image display device 20 from among several image data (Shinkansen, Mt. Fuji, Roppongi Hills, sunset, etc.). This selection is performed by moving the menu cursor with a known cross key 43 constituting the portable terminal operation unit 301 and pressing the enter key 44. Here, as shown in FIG. 10B, the case where the image data of Mt. Fuji is selected is shown. When the “*” key 41 constituting the mobile terminal operation unit 301 is pressed in this state, image data corresponding to the image displayed on the screen 14 which is the mobile terminal display unit 302 is transmitted to the image display device 20 by infrared communication. Operation is performed.

  The “#” key 42 is an erase button, and prepares to send a command to erase the image displayed on the screen 14 to the image display device 20 by infrared communication. The “1” key 31 is a command to enlarge the image (operation information), the “3” key 33 is a command to reduce the image (operation information), and the “4” key 34 is a command to rotate the image 90 ° to the left. (Operation Information), “6” key 36 prepares to send a command (operation information) to rotate the image 90 ° rightward to image display device 20 by infrared communication. Further, the “5” key 35 is at the top of the image display device 20, the “7” key 37 is at the left side of the image display device 20, the “8” key 38 is at the center of the image display device 20, and the “9” key 39 is at the center. On the right side of the image display device 20, a “0” key 40 transmits additional data for displaying the writing (for example, a heart mark) superimposed on the lower portion of the image display device 20 to the image display device 20 by infrared communication. Prepare.

  When the key is operated as described above and preparation for transmission to the image display device 20 by infrared communication is performed, the laser light is irradiated from the laser light irradiation unit 316 (FIG. 7) of the portable terminal 10, which is shown in FIG. 10 (c). Thus, the message “When the infrared light receiving part of the television is in the laser beam ring, press“ * ”again” is displayed on the screen 14. When the user confirms that the infrared light receiving unit 201 of the television has been placed in the ring of laser light and presses the “*” key 41, the image data, operation information, additional data, and the like remain while the laser light irradiation continues. Is transmitted to the image display device 20 via the infrared irradiation unit 315. When the transmission is completed, the laser beam irradiation by the laser beam irradiation unit 316 is terminated.

  FIG. 11 is a flowchart illustrating an example of a processing flow of the image display apparatus 20 according to the first embodiment of the present invention. This flowchart shows a process in which the image display apparatus 20 receives and displays image data from the mobile terminal 10. Here, the image display device 20 performs infrared communication using the first transmission / reception processing unit 409, the first infrared irradiation unit 412, and the first infrared light receiving unit 413 of FIG. 8 as the transmission / reception processing unit, infrared irradiation unit, and infrared light reception unit. The case where it performs is demonstrated.

  First, the first transmission / reception processing unit 409 receives image data transmitted from the mobile terminal 10 via the first infrared light receiving unit 413 (step S201). The image data reception processing unit 406 stores the received image data by holding it in the received image data holding unit 402 (step S202). The image data reception processing unit 406 deletes the previous additional data held by the received additional data holding unit 404 by discarding it (step S203). The display image creation unit 403 displays image data on the large screen display unit 401 (step S204).

  FIG. 12 is a diagram illustrating an example of a method for outputting image data to the large screen display unit 401 (FIG. 8) of the image display device 20 according to the first embodiment of the present invention. The portable terminal 10 sequentially transmits a plurality of images g1 to g5 held in the image data holding unit 310 to the image display device 20 using infrared communication, and sequentially displays them as a slide show on the image display device 20. The mobile terminal 10 sequentially displays the five images g1 to g5 on the screen 14 and sequentially transmits the five image data to the image display device 20. The image display device 20 realizes a slide show by outputting the images g1 to g5 based on the received image data to the screen 21 at regular intervals (for example, every 5 seconds).

  When a plurality of images are transmitted as in a slide show, or when an image is a moving image, the amount of data to be transmitted becomes large and transmission takes time. Further, when the image data received by the image display device 20 is immediately displayed, it is necessary to transmit the image data at a constant interval (for example, every 5 seconds) on the mobile terminal 10 side. In both cases, it is necessary to keep the portable terminal 10 in a position where the infrared light receiving unit 201 of the image display device 20 is within the infrared reachable range 13 irradiated by the portable terminal 10 until the transmission is completed. In such a case, while the infrared communication is continued, the projected pattern 11 of the laser light continues to exist visually, so that the infrared light receiving unit of the image display device 20 is placed in the infrared reachable range 13 emitted from the mobile terminal 10. It becomes easy to keep holding the portable terminal 10 in a position where 201 is stored.

(Second Embodiment)
Next, a second embodiment of the present invention will be described. Since the configuration of the mobile terminal 10 and the image display device 20 according to the present embodiment is the same as the configuration of the mobile terminal 10 (FIG. 7) and the image display device 20 (FIG. 8) according to the first embodiment, the description thereof will be given. Omitted.

  FIGS. 13A and 13B are diagrams illustrating an example of a method for outputting image data to the screen 21 of the image display device 20 according to the second embodiment of the present invention. Here, after the image displayed on the mobile terminal 10 is transmitted to the image display device 20 using infrared communication and displayed on the screen 21 of the image display device 20, the operation information for instructing the rotation from the mobile terminal 10. Is transmitted to the image display device 20, and the image is rotated and displayed on the screen 21 of the image display device 20.

  When the mobile terminal 10 is a mobile phone with a camera, the mobile phone with a camera may be taken while holding the camera vertically or may be taken while holding the camera horizontally. As long as it is not recognized whether the camera-equipped mobile phone is held vertically or horizontally, the upward direction of the image does not necessarily coincide with the upward direction when viewed by the user. Do not mean. When such image data is transmitted from the portable terminal 10 to the image display device 20, the image display device 20 is positioned, for example, in the left direction on the screen 21 in the upper direction when the user views it as shown in FIG. There is a case. That is, the image displayed on the screen 21 is displayed in a state rotated 90 ° to the left. In such a case, by pressing the “6” key 36 of the mobile terminal 10, a command (operation information) for rotating the image 90 ° rightward is transmitted. As a result, the image is displayed again on the image display device 20 after being rotated 90 ° to the right (FIG. 13B). It should be noted that the laser light projection pattern 11 indicating the infrared reachable range 13 is visually present both when transmitting image data and when transmitting a command (operation information) that rotates 90 ° rightward. desirable.

  In the image display device 20, an image rotated 90 ° rightward as shown in FIG. 13B is enlarged as compared with an image rotated 90 ° leftward as shown in FIG. 13A. This is realized by enlarging the screen of the image display device 20 as large as possible within a range that fits on the screen 21 of the image display device 20 while maintaining the aspect ratio. Note that the image of FIG. 13A and the image of FIG. 13B may be displayed on the screen 21 with the same size.

FIG. 14 is a flowchart illustrating an example of a process flow of the mobile terminal 10 according to the second embodiment of the present invention. This flowchart shows processing in the case of rotating the image displayed on the screen 21 of the image display device 20.
First, the user of the mobile terminal 10 instructs the rotation of the image displayed on the screen 21 of the image display device 20 by operating the mobile terminal operation unit 301 (step S301). The image operation information transmission unit 308 creates operation information for instructing rotation (step S302). The transmission / reception processing unit 312 transmits operation information to the image display device 20 via the infrared irradiation unit 315 (step S303). Although the case where the operation information is image rotation is described here, the present invention is not limited to this, and may be operation information regarding other processes such as image enlargement or reduction.

  FIG. 15 is a flowchart illustrating an example of a processing flow of the image display device 20 according to the second embodiment of the present invention. This flowchart shows processing when the image display device 20 receives operation information for instructing rotation from the mobile terminal 10. Here, the image display device 20 performs infrared communication using the first transmission / reception processing unit 409, the first infrared irradiation unit 412, and the first infrared light receiving unit 413 of FIG. 8 as the transmission / reception processing unit, infrared irradiation unit, and infrared light reception unit. The case where it performs is demonstrated.

  First, the first transmission / reception processing unit 409 receives operation information from the mobile terminal 10 via the first infrared light receiving unit 413 (step S401). The image operation information reception processing unit 405 holds the received operation information in the received image data holding unit 402 in association with the image data output to the large screen display unit 401 (step S402). The display image creation unit 403 reads image data from the received image data holding unit 402 and operation information held in association with the image data (step S403). The display image creating unit 403 displays the large screen display unit 401 by outputting the image data reflecting the operation information (step S404). Here, since the operation information relates to a rotation command, the image is rotated and output to the screen display unit 401.

FIG. 16 is a sequence diagram illustrating an example of a process flow between the mobile terminal 10 and the image display device 20 according to the modification of the second embodiment of the present invention.
First, the mobile terminal 10 transmits the image data A with the file name A ′, which is identification information of the image data, to the image display device 20 (step S501). The image display device 20 holds the received image data A and the file name A ′ as a set in the received image data holding unit 402. At the same time, the image display device 20 displays an image based on the image data A on the screen 21 (step S502).
The portable terminal 10 transmits a command (operation information R) for rotating the image 90 ° rightward to the image display device 20 (step S503). The image display device 20 holds the received operation information R, the image data A, and the file name A ′ of the displayed image as a set and holds them in the operation information holding unit in the received image data holding unit 402. Further, the image display device 20 performs an operation of rotating the image displayed on the screen 21 by 90 ° in the right direction, and redisplays the image rotated by 90 ° in the right direction (step S504).

Next, the portable terminal 10 transmits the image data B with the file name B ′, which is identification information of the image data, to the image display device 20 (step S505). The image display apparatus 20 sets the received image data B and the file name B ′ as a set, holds the received image data B in the received image data holding unit 402, and displays an image based on the image data B (step S506).
When the user of the portable terminal 10 wants to view the image data A again on the image display device 20, the portable terminal 10 includes only the file name A ′ from the portable terminal 10 to the image display device 20, and does not include the image file A. Information is transmitted (step S507). The image display device 20 refers to the received file name A ′ and holds the received image data as a pair with the file name A ′ and the image data A held in the received image data holding unit 402 as a set with the file name. Operation information R (operation information for rotating the image 90 ° rightward) held in the operation information holding unit in the unit 402 is read out. Then, the image display device 20 redisplays on the screen 21 an image obtained by performing an operation based on the read operation information R (operation information for rotating the image 90 ° to the right) with respect to the image based on the read image data A. (Step S508).

  Accordingly, in step S507, the image display device 20 can display an image based on the image data A without the mobile terminal 10 transmitting the image data A. Further, in step S507, the image display device 20 performs an operation based on the operation information R transmitted by the portable terminal 10 in step S508, even if the portable terminal 10 does not retransmit the operation information R transmitted by the portable terminal 10 in step S501. The reflected image can be displayed.

(Third embodiment)
Next, a third embodiment of the present invention will be described. Since the configuration of the mobile terminal 10 and the image display device 20 according to the present embodiment is the same as the configuration of the mobile terminal 10 (FIG. 7) and the image display device 20 (FIG. 8) according to the first embodiment, the description thereof will be given. Omitted.

  FIG. 17 is a diagram for explaining an example of processing between the mobile terminal 10 and the image display device 20 according to the third embodiment of the present invention. Here, after the image displayed on the screen 14 by the mobile terminal 10 is transmitted to the image display device 20 using infrared communication and displayed on the screen 21 of the image display device 20, a graffiti or the like is displayed from the mobile terminal 10. The additional data is transmitted to the image display device 20, and the image display device 20 displays the additional data superimposed on the image data. Further, the mobile terminal 10 acquires the additional data and overlays the additional data on the image data on the screen 14. it's shown. In this specification, graffiti refers to displaying additional data such as characters and figures superimposed on image data such as photographs.

  The mobile terminal 10 (FIG. 17B) first transmits an image (main image g6: for example, a photograph) displayed on the mobile terminal 10 to the image display device 20, and displays it on the screen 21 of the image display device 20. Next, the portable terminal 10 (FIG. 17C) creates additional data m1 (for example, a graffiti such as a heart mark drawn using pen input) for the image displayed on the image display device 20, and the additional data. m1 is transmitted to the image display device 20. The image display device 20 displays the image g7 in which the received additional data m1 is superimposed on the displayed image g6 (the additional image (= the heart mark graffiti is superimposed on the main image (= photo)) (FIG. 17 ( a)). Next, the mobile terminal 10 (FIG. 17D) requests data for the image g7 displayed on the image display device 20 (an image in which a heart symbol doodle is superimposed on the photograph), and responds to the response from the image display device 20. Based on this, the mobile terminal 10 displays the image g7 (an image in which a heart symbol doodle is superimposed on the photograph). The image g7 displayed on the screen 14 of the mobile terminal 10 can be attached to an e-mail and transmitted to another device via a mobile phone network or the like.

When graffiti is performed by superimposing the additional data m1 on the image data g6 that is a photograph displayed on the image display device 20, even if the image data g6 is not transmitted from the mobile terminal 10, the graffiti is performed only by transmitting the additional data m1. be able to. Thereby, communication charges can be reduced. The mobile terminals 10 shown in FIGS. 17B to 17D may be the same mobile terminal or different mobile terminals.
By using a different mobile terminal 10 as the mobile terminal 10 shown in FIGS. 17B to 17D, another person can make a graffiti on the image g <b> 7 displayed on the screen 21 of the image display device 20. That is, the image g7 can be created by superimposing the additional data m1 on the displayed image.

FIG. 18 is a diagram for explaining another example of processing between the mobile terminal 10 and the image display device 20 according to the third embodiment of the present invention. After the image data shown in FIG. 18E displayed on the screen 14 of the first portable terminal 10a is transmitted to the image display device 20 using infrared communication and displayed on the screen 21 of the image display device 20. Additional data such as graffiti from the first mobile terminal 10a (FIG. 18 (b)), the second mobile terminal 10b (FIG. 18 (c)), and the third mobile terminal 10c (FIG. 18 (d)). m2, m3, and m4 are transmitted to the image display device 20. Then, the image display device 20 creates and displays the image g8 by superimposing the additional data m2, m3, and m4 on the image data. Further, the image display device 20 acquires the additional data m2, m3, and m4 from the image display device 20. The additional data is superimposed and displayed on the first portable terminal 10a. In this case, the image displayed on the screen of the first portable terminal 10a changes from FIG. 18 (e) to FIG. 18 (f).
As shown in FIG. 18A, the image display device 20 includes three infrared light receiving units 201a, 201b, and 201c. The infrared light receiving unit 201a corresponds to the first transmission / reception processing unit 409, the first infrared irradiation unit 412, and the first infrared light receiving unit 413 in FIG. The infrared light receiving unit 201b corresponds to the second transmission / reception processing unit 410, the second infrared irradiation unit 414, and the second infrared light receiving unit 415 in FIG. The infrared light receiving unit 201c corresponds to the third transmission / reception processing unit 411, the third infrared irradiation unit 416, and the third infrared light receiving unit 417 in FIG.

The mobile terminal 10 a (FIG. 18B) creates character data “very fun” as the additional data m 2 for the image displayed on the screen 21 of the image display device 20, and uses the additional data m 2 of the image display device 20. It transmits toward the 1st infrared light-receiving part 201a. The user of the portable terminal 10a confirms that the first infrared light receiving unit 201a is included in the projected pattern 11a of the laser light, but the second infrared light receiving unit 201b and the third infrared light receiving unit 201c are not included. Perform infrared communication.
Similarly, the user of the mobile terminal 10 (FIG. 18C) creates character data “May play” as additional data m3 for the image displayed on the screen 21 of the image display device 20, and the additional data m3 is transmitted toward the second infrared light receiving unit 201b of the image display device 20. In addition, the user of the mobile terminal 10c (FIG. 18D) creates character data “Lovely Girls” as additional data m4 for the image displayed on the screen of the image display device 20, and uses the additional data m4 as the image. It transmits toward the 3rd infrared light-receiving part 201c of the display apparatus 20. FIG.

  The image display device 20 displays the additional data depending on whether the additional data is received by the first infrared light receiving unit 201a, the second infrared light receiving unit 201b, or the third infrared light receiving unit 201c. Change the way. That is, different display attributes are assigned to the additional data depending on which infrared light receiving unit has received the additional data. For example, the additional data m2 “very fun” received by the first infrared light receiving unit 201a installed on the left side is placed on a yellow translucent balloon and displayed on the left side of the screen 21 of the image display device 20. Overlay with data. Further, the additional data m3 “May play” received by the second infrared light receiving unit 201b installed in the center is placed on a green translucent balloon and near the center of the screen 21 of the image display device 20. The image data is displayed so as to overlap with the image data. Further, the additional data m4 “Lovely Girls” received by the third infrared light receiving unit 201c installed on the right side is placed on a blue translucent balloon and displayed on the right side of the screen 21 of the image display device 20. Overlay with data. In this way, the display attribute of the additional data to be overlaid on the image data by the image display device 20 varies depending on which infrared light receiving unit has received the image.

  The display attributes include the display color (yellow, green, blue, etc.), the display position (left side, center, right side, etc. of the screen 21), the shape of the additional data m1 such as a balloon shape or a heart-shaped pattern (FIG. 17 ( c)) can be used. Alternatively, based on the additional image based on the additional data m2 received by the first infrared light receiving unit 201a, the additional image based on the additional data m3 received by the second infrared light receiving unit 201b, and the additional data m4 received by the third infrared light receiving unit 201c. For example, the display timing of displaying the additional image every other second may be set as one of the display attributes.

  FIG. 19 is a flowchart illustrating an example of a process flow of the mobile terminal 10 according to the third embodiment of the present invention. In the flowchart, the image data A displayed on the first portable terminal 10a is transmitted to the image display device 20 using infrared communication and displayed on the screen 21 of the image display device 20, and then the first to first images are displayed. 3 transmits additional data m2 to m4 such as graffiti from the mobile terminals 10a to 10c to the image display device 20, and the image display device 20 displays the additional data m2 to m4 on the image data A, and further displays the image data. 20, when the additional data m2 to m4 are acquired from the image 20 and the additional data m2 to m4 are superimposed on the image and displayed on the screen 14 of the first mobile terminal 10a, the processing between the mobile terminal 10a and the image display device 20 is performed. Show.

First, the portable terminal 10a transmits the image data A to the image display device 20 toward the first infrared light receiving unit 201a (step S601). The image display device 20 holds the received image data A and displays an image based on the image data A.
Next, the portable terminal 10a transmits additional data m2 (for example, character information “for example, very fun”) to the first infrared light receiving unit 201a of the image display device 20 (step S602). The image display device 20 determines the display attribute z2 of the additional data m2 (displayed on the left side of the screen 21 in a yellow balloon) based on the reception of the additional data m2 by the first infrared light receiving unit 201a. The additional data m2 is displayed over the displayed image data A, and the additional data m2 and the display attribute z2 of the additional data are held.

Next, the portable terminal 10b transmits the additional data m3 (for example, character information of “Let's play again”) toward the second infrared light receiving unit 201b of the image display device 20 (step S603). Based on the reception of the additional data m3 by the second infrared light receiving unit 201b, the image display device 20b determines the display attribute z3 (displayed in the vicinity of the center of the screen 21 in a green balloon) of the additional data m3. Thus, the additional data m3 is displayed over the displayed image data A, and the additional data m3 and the display attribute z3 of the additional data m3 are held.
Next, the mobile terminal 10c transmits additional data m4 (for example, character information “Lovely Girls”) to the third infrared light receiving unit 201c of the image display device 20 (step S604). Based on the reception of the additional data m4 by the third infrared light receiving unit 201c, the image display device 20 determines the display attribute z4 (displayed on the right side of the screen 21 in a blue balloon) of the additional data m4, The additional data m4 is displayed over the displayed image data A, and the additional data m4 and the display attribute z4 of the additional data m4 are held.

Next, the mobile terminal 10a transmits a data request toward the first infrared light receiving unit 201a toward the image display device 20 (step S605). The image display device 20 takes out a set of the additional data m2 to m4 and the display attributes z2 to z4 displayed so as to overlap the displayed image data A, and directs the first infrared irradiation unit toward the mobile terminal 10a. It transmits via 201a (step S606). The portable terminal 10a creates image data A ″ that is superimposed on the stored image data A based on the display attributes z2 to z4 received from the received additional data m2 to m4, and the image data A ″. An image based on is displayed on the screen 14. Note that the mobile terminal 10a can also send the created image data A ″ to another device by attaching it to a mail (step S607).
In step S606 described above, the additional data m2, m3, and m4 and the display attributes z2, z3, and z4 are transmitted from the image display device 20 to the mobile terminal 10a. However, the present invention is not limited to this. Instead, only the additional data m3, m4 and the display attributes z3, z4 that have not been transmitted from the mobile terminal 10a to the image display device 20 may be transmitted.

FIG. 20 is a flowchart illustrating an example of a process flow of the mobile terminal 10a according to the third embodiment of the present invention. This flowchart shows processing when additional data such as graffiti is transmitted to the image display device 20.
First, the user of the mobile terminal 10a operates the mobile terminal operation unit 301 to input graffiti on the image data displayed on the screen 14 of the mobile terminal 10a and the screen 21 of the image display device 20, that is, The additional data is input (step S701). The additional data transmission unit 307 creates additional data m2 to be transmitted to the image display device 20 based on the input additional data (step S702). The transmission / reception processing unit 312 transmits the additional data m2 to the image display device 20 via the infrared irradiation unit 315 (step S703).

FIG. 21 is a flowchart illustrating an example of a processing flow of the image display device 20 according to the third embodiment of the present invention. This flowchart shows processing when additional data such as graffiti is received from the mobile terminal 10 and the additional data is displayed on the screen 21 of the image display device 20 so as to overlap the image data.
First, one of the transmission / reception processing units 201a to 201c receives additional data from the mobile terminal 10 (step S801). Then, it is determined which transmission / reception processing units 201a to 201c have received the additional data (step S802).
When the first transmission / reception processing unit 201a receives the additional data, the image operation information reception processing unit 405 displays the additional data and attribute information associated with the additional data (for example, “position: left side”, “color”). : Yellow ”) is associated and held in the received additional data holding unit 404 (step S803). Then, the process proceeds to step S806.

On the other hand, when the second transmission / reception processing unit 201b receives the additional data, the image operation information reception processing unit 405 displays the additional data and attribute information associated with the additional data (for example, “position: center”, “Color: Green”) is stored in association with the received additional data storage unit 404 (step S804). Then, the process proceeds to step S806.
On the other hand, when the additional data is received by the third transmission / reception processing unit 201c, the image operation information reception processing unit 405 displays the additional data and attribute information associated with the additional data (for example, “position: right side”, “Color: Blue”) is associated and held in the received additional data holding unit 404 (step S805). Then, the process proceeds to step S806.

Then, the display image creation unit 403 reads the image data from the received image data holding unit 402, and displays the additional data stored in the received additional data holding unit 402 and the display attribute (additional data stored in the additional data). The display color and position are read out (step S806). There may be a plurality of additional data and display attributes read in step S806.
The display image creation unit 403 displays the read one or more additional data on the read image data on the large screen display unit 401 reflecting the color, position, etc. based on the display attributes (step S807). .

FIG. 22 is a flowchart illustrating an example of a process flow of the mobile terminal 10 according to the third embodiment of the present invention. This flowchart shows processing for acquiring additional data created by graffiti or the like by requesting the data from the image display device 20, creating image data on which the acquired additional data is superimposed, and sending it by e-mail.
Here, prior to the processing of FIG. 22, the user of the mobile terminal 10 reads out image data to be graffitied from the image data holding unit 310 and transmits it to the image display device 20 via the infrared irradiation unit 315. is doing.

  A user of the mobile terminal 10 who wants to send the image displayed on the image display device 20 to a friend as an attachment to an e-mail, operates the mobile terminal operation unit 301 to display the image displayed on the image display device 20. The portable terminal 10 is instructed to capture (step S901). Thus, the additional data acquisition processing unit 306 instructs the transmission / reception processing unit 312 to acquire additional data (step S902). The transmission / reception processing unit 312 transmits a data request for requesting additional data to the image display device 20 via the infrared irradiation unit 315 (step S903). The transmission / reception processing unit 312 receives a set of one or more additional data and display attributes (such as a position and a color for displaying the additional data) via the infrared light receiving unit 314 (step S904). The additional data acquisition processing unit 306 instructs the image data combining unit 311 to combine the image data and the additional data (step S905). The image data synthesis unit 311 reads out the image data transmitted to the image display device 20 from the image data holding unit 310 (step S906).

The image data synthesis unit 311 synthesizes image data by superimposing one or more additional data reflecting display attributes such as color and position on the read image data, and holds the image data in the image data holding unit 310 ( Step S907). The display image creation unit 303 displays the combined image data on the mobile terminal display unit 302 based on the instruction from the additional data acquisition processing unit 306 (step S908).
Next, the mail transmission processing unit 304 determines whether or not the user of the mobile terminal 10 has instructed transmission of mail by operating the mobile terminal operation unit 301 (step S909). If the mail transmission is not instructed, the process according to the flowchart of FIG. 22 ends. On the other hand, when an email transmission instruction is given, the email transmission processing unit 304 reads the image data synthesized from the image data holding unit 310 and attaches it to the email to be transmitted (step S910). The mail transmission processing unit 304 transmits a mail attached with the synthesized image data to another device via the network communication unit 305 (step S911).

FIG. 23 is a flowchart illustrating an example of a process flow of the image display apparatus 20 according to the third embodiment of the present invention. This flowchart shows processing in a case where additional data such as graffiti is transmitted to the mobile terminal 10 in response to a data request transmitted from the mobile terminal 10. Here, the image display device 20 performs infrared communication using the first transmission / reception processing unit 409, the first infrared irradiation unit 412, and the first infrared light receiving unit 413 of FIG. 8 as the transmission / reception processing unit, infrared irradiation unit, and infrared light reception unit. The case where it performs is demonstrated.
First, the first transmission / reception processing unit 409 receives a data request via the first infrared light receiving unit 413 (step S1001). The additional data return processing unit 408 reads a set of one or more additional data and a display attribute associated with the additional data from the received additional data holding unit 404 (step S1002). The first transmission / reception processing unit 409 transmits a set of one or more additional data and a display attribute associated with the additional data (step S1003).

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described. Since the configuration of the mobile terminal 10 and the image display device 20 according to the present embodiment is the same as the configuration of the mobile terminal 10 (FIG. 7) and the image display device 20 (FIG. 8) according to the first embodiment, the description thereof will be given. Omitted.
In the third embodiment, the case where the mobile terminal 10a transmits a data request to the image display device 20 has been described. However, in this embodiment, the user of the mobile terminal 10b also displays the image displayed on the image display device 20. Data is acquired and displayed on the screen 14 of the mobile terminal 10b, or transmitted to another person as an email attachment image.

FIG. 24 is a sequence diagram showing an example of a process flow between the mobile terminal 10 and the image display device 20 according to the fourth embodiment of the present invention. The processes in steps S1101 to S1104 and S1107 in FIG. 24 are the same as the processes in steps S601 to S604 and S607 in FIG.
The portable terminal 10a transmits a data request toward the first infrared light receiving unit 413 of the image display device 20 (step S1105). The image display apparatus 20 determines whether or not the mobile terminal that is the transmission source that has transmitted the data request is the same as the mobile terminal that is the transmission source that has transmitted the image data A. If it is determined that they are the same, the image display device 20 adds the additional data m2, m3, and m4 displayed on the image data displayed on the screen 21 and the display attributes z2, z3, and z4. Are transmitted to the portable terminal 10a via the first infrared irradiation unit 412 (step S1106).

In the portable terminal 10a, an image superimposed on the image data A held in the image data holding unit 305 based on the display attributes z2, z3, and z4 received from the received additional data m2, m3, and m4 is created. indicate. The created image data can be attached to a mail and transferred to another device (step S1107).
On the other hand, the mobile terminal 10b transmits a data request to the second infrared light receiving unit 415 of the image display device 20 (step S1108). The image display device 20 determines that the mobile terminal that is the transmission source that has transmitted the data request is different from the mobile terminal that is the transmission source that has transmitted the image data A. As a result of determining that they are different, the image display device 20 adds the additional data m2, m3, and m4 displayed on the image data displayed on the screen 21 and the display attributes z2, z3, and z4. The set is read out and transmitted to the portable terminal 10b together with the image data A via the second infrared irradiation unit 414 (step S1109).
The portable terminal 10b creates and displays superimposed image data on the received image data A based on the display attributes z2, z3, and z4 received from the received additional data m2, m3, and m4. The created image data can be attached to an email and transferred to another device (step S1110).
In the description of FIG. 24 described above, a case has been described in which the additional data m2 to m4 and the display attributes z2 to z4 corresponding to the additional data m2 to m4 are transmitted to the mobile terminal in steps S1106 and S1109. However, it is not limited to such a configuration. For example, the additional data m2 to m4 may be transmitted to the mobile terminal, and the display attributes z2 to z4 may not be transmitted to the mobile terminal. By performing such processing, the amount of communication between the portable terminal 10a and the image display device 20 can be reduced.

The following method can be used as a method of determining whether or not the mobile terminal that is the transmission source that has transmitted the data request is the same as the mobile terminal that is the transmission source that has transmitted the image data A.
As a first determination method, a method of including transmission source information in communication data including image data A and communication data including a data request can be used. As communication data transmission information, an IP (Internet Protocol) address, a MAC (Media Access Control) address, a mobile phone number, and the like uniquely assigned to a mobile terminal for communication can be used.

  As a second determination method, a method of including information on whether or not the mobile terminal 10a holds the image data A displayed on the display unit 21 of the image display device 20 in communication data including a data request is included. Can be used. For example, the file name of the image data A can be used as the information indicating whether or not the image data is held. The image display device 20 refers to the file name included in the data request. If the image display device 20 matches the file name of the image data currently displayed on the screen 21, the source mobile terminal that sent the data request It determines with it being the same as the portable terminal which is the transmission source which sent data A.

As a third determination method, a method of determining whether the infrared light receiving unit that has received the image data A is the same as the infrared light receiving unit that has received the data request can be used. For example, when the image display device 20 receives the image data A via the first infrared light receiving unit 413 and receives the data request by the first infrared light receiving unit 413, the image display device 20 has sent the data request. It is determined that the mobile terminal that is the transmission source is the same as the mobile terminal that is the transmission source that sent the image data A. When the image display device 20 receives the image data A via the first infrared light receiving unit 413 and receives the data request by the second infrared light receiving unit 415 or the third infrared light receiving unit 417, an image display is performed. The apparatus 20 determines that the mobile terminal that is the transmission source that has transmitted the data request is different from the mobile terminal that is the transmission source that has transmitted the image data A.
The additional data reply processing unit 408 returns the additional data and the display attribute to the mobile terminal 10 when the infrared light receiving unit that has received the image data is the same as the infrared light receiving unit that has received the data request. If they are different, the image data may be returned to the portable terminal 10 together with the additional data and the display attribute.

FIG. 25 is a flowchart illustrating an example of a process flow of the image display apparatus 20 according to the fourth embodiment of the present invention. Here, the image display device 20 performs infrared communication using the first transmission / reception processing unit 409, the first infrared irradiation unit 412, and the first infrared light receiving unit 413 of FIG. 8 as the transmission / reception processing unit, infrared irradiation unit, and infrared light reception unit. The case where it performs is demonstrated.
First, the first transmission / reception processing unit 409 receives an additional data request via the first infrared light receiving unit 413 (step S1201). The additional data return processing unit 408 reads a set of one or more additional data and a display attribute associated with the additional data from the received additional data holding unit 404 (step S1202). The additional data return processing unit 408 checks the transmission source of the image data held in the received image data holding unit 404 (step S1203).
Then, the additional data reply processing unit 408 determines whether or not the image data transmission source and the data request transmission source are the same (step S1204).

When the transmission source of the image data and the transmission source of the data request are not the same, the first transmission / reception processing unit 409 includes the image data, the one or more additional data, and the display attribute corresponding to the additional data. The set is transmitted to the mobile terminal 10 that is the transmission source (step S1205).
On the other hand, when the transmission source of the image data and the transmission source of the data request are the same, the first transmission / reception processing unit 409 sets a set of one or more additional data and a display attribute corresponding to the additional data. Then, the data is transmitted to the mobile terminal 10 that is the transmission source (step S1205).

  In the above description, the image display device 20 sends the image data A, the additional data m2, its display attribute z2, the additional data m3, its display attribute z3, the additional data m4, and its display attribute z4 to, for example, the portable terminal 10b. The mobile terminal 10b creates image data in which the additional data m2, m3, and m4 are overlaid. On the other hand, an image displayed on the image display device 20 (an image obtained by superimposing the additional data m2, m3, and m4 on the image data A) is created, and the created image data is transmitted to the mobile terminal 10. Also good. In this case, if NO is determined in step S1204 in FIG. 25, the additional data return processing unit 408 displays the image data, the one or more additional data, and the display attribute of the additional data instead of the process of step S1205. Based on the pair, the composite image data for reply is created, and the transmission / reception processing unit 312 performs processing for transmitting the composite image data for reply to the mobile terminal 10b.

FIG. 26 is a flowchart illustrating an example of a process flow of the mobile terminal 10 according to the fourth embodiment of the present invention. The processes in steps S1301 to S1303 and S1313 to S1316 in FIG. 26 are the same as steps S901 to S903 and S908 to S911 in FIG.
After the processing in step S1303, the transmission / reception processing unit 312 receives data returned from the image display device 20 in response to the data request transmitted in step S1303 via the infrared light receiving unit 314 (step S1304). Then, it is determined whether the received data includes image data (step S1305).

  If it is determined that the received data does not include image data, the transmission / reception processing unit 312 extracts a set of one or more additional data and a display attribute of the additional data from the received data. (Step S1306). The additional data acquisition processing unit 306 instructs the image data combining unit 311 to combine the image data and the additional data (step S1307). The image data composition unit 311 reads the image data transmitted to the image display device 20 from the image data holding unit 310 (step S1308). The image data synthesizing unit 311 synthesizes the received additional data according to the display attributes on the read image data, and holds the combined image data in the image data holding unit 310 (step S1309).

  On the other hand, if it is determined in step S1305 that the received data includes image data, the transmission / reception processing unit 312 selects the image data, one or more additional data, from the received data, A pair with the display attribute of the additional data is extracted (step S1310). The additional data acquisition processing unit 306 instructs the image data combining unit 311 to combine the image data and the additional data (step S1311). The image data synthesizing unit 311 synthesizes the additional data on the image data acquired in step S1310 according to the respective display attributes, and holds the combined image data in the image data holding unit 310 (step S1312).

(Fifth embodiment)
Next, a fifth embodiment of the present invention will be described.
FIG. 27 is a diagram showing a configuration of a wireless adapter 1000 according to the fifth embodiment of the present invention. The wireless adapter 1000 includes a housing 1001 and a cable unit 1002. The housing 1001 includes a received image data holding unit 402, a display image creation unit 403, a received additional data holding unit 404, an image operation information reception processing unit 405, an image data reception processing unit 406, other than the large screen display unit 401 in FIG. Additional data reception processing unit 407, additional data reply processing unit 408, first transmission / reception processing unit 409, second transmission / reception processing unit 410, third transmission / reception processing unit 411, first infrared irradiation unit 412, first infrared light receiving unit 413, first 2 infrared irradiation part 414, 2nd infrared light reception part 415, 3rd infrared irradiation part 416, and 3rd infrared light reception part 417 are provided. Further, an output terminal for outputting a video signal is provided instead of the large screen display unit 401.
The 2nd infrared irradiation part 414 and the 2nd infrared light-receiving part 415 communicate by the infrared rays transmitted / received from the predetermined transmission direction D2 via the condensing lens 1011b.
The first infrared irradiation unit 412 and the first infrared light receiving unit 413 communicate with each other by infrared rays transmitted and received from the transmission direction D3 that forms an angle of 30 ° from the predetermined transmission direction D2 via the condenser lens 1011a.
Further, the third infrared irradiation unit 416 and the third infrared light receiving unit 417 transmit and receive from the transmission direction D4 that forms an angle of 30 ° in the direction opposite to the transmission direction D3 from the predetermined transmission direction D2 via the condenser lens 1011c. Communication is performed using infrared rays.

  One end of the cable portion 1002 is connected to the housing 1001. In addition, the other end of the cable portion 1002 is branched into three, and a plurality of output terminals are provided at the respective ends. Here, a D terminal / HDMI (High-Definition Multimedia Interface) 1002a, a composite video terminal / audio terminal 1002b, and an S terminal 1002c are provided as a plurality of output terminals. These terminals 1002a, 1002b, and 1002c are connected to input terminals of the television receiver, thereby displaying an image generated by the display image creating unit 403 on the screen of the television receiver. Wireless adapter 1000 inputs and outputs video and / or audio signals to and from the television receiver to which terminals 1002a, 1002b, and 1002c are connected.

  FIG. 28 is a diagram illustrating an example of how to attach the wireless adapter 1000 to the television receiver according to the fifth embodiment of the present invention. As shown in FIG. 28, the condensing lens 1011b faces the front of the screen 21 in a state where the wireless adapter 1000 is attached to or attached to the image display device 20. Further, on both sides of the condensing lens 1011b, a condensing lens 1011a used when communication is performed by infrared rays transmitted and received from the direction of 30 ° to the left with respect to the front, and a direction of 30 ° to the right with respect to the front It arrange | positions so that the condensing lens 1011c utilized when communicating by the infrared rays transmitted / received from may be located.

In this way, by attaching the three condenser lenses 1011a, 1011b, and 1011c to the television receiver that is the image display device 20 at different angles, infrared rays from different directions transmitted by the mobile terminal 10 can be received. it can. Here, the condensing lenses 1011a, 1011b, and 1011c having a directivity angle of ± 15 degrees are used, and infrared rays are transmitted and received from directions of 45 ° to the left and right of the image display device 20 and 90 ° in total. It becomes possible to perform communication.
As a mounting position of the wireless adapter 1000 in the television receiver which is the image display device 20, any position that does not block the image displayed on the screen 21 may be used. However, as shown in FIG. It may be arranged near the remote control signal light receiving unit.
Note that terminals 1002 a, 1002 b, and 1002 c provided on the cable portion 1002 of the wireless adapter 1000 are connected to video input terminals of a television receiver that is the image display device 20.

According to the first, third, fourth, and fifth embodiments of the present invention described above, graffiti is input on a mobile terminal used by a user using communication such as infrared communication, that is, additional data is input, Graffiti can be performed while checking images on a large screen image display device such as a television receiver.
In addition, when multiple users perform graffiti at the same time on a large-screen image display device, that is, when additional data can be superimposed on image data, Since whether or not to transmit data including image data from the image display device is determined depending on whether or not the mobile terminal holds image data, the amount of communication between the mobile terminal and the image display device is reduced. Can be suppressed.
Further, according to the second embodiment of the present invention described above, it is necessary to repeatedly perform the same operation on the image by storing operation information about the image displayed on the large screen of the image display device. Therefore, the operability for the user can be improved.

  Note that the processing performed by the portable terminal and the image display device of the present invention can also be realized as a program. This program is stored in a computer-readable recording medium, and each process is realized by the program. Examples of recording media include tape systems such as magnetic tapes and cassette tapes, disk systems such as magnetic disks such as floppy (registered trademark) disks and hard disks, and optical disks such as CD-ROM / MO / MD / DVD, and IC cards. Or a card system such as an optical card, a medium carrying a fixed program including a semiconductor memory such as a mask ROM, FPROM, EEPROM, flash ROM or the like. The recording medium may be configured by, for example, a memory stick, a compact flash (registered trademark) card, a smart media, an SD card, a multimedia card, a micro drive, or the like.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

It is the schematic which shows the structure of the information processing system by the 1st Embodiment of this invention. It is a block diagram of the light emission part 15 which makes the cylindrical shape of the portable terminal 10 by the 1st Embodiment of this invention. It is a figure which shows an example of the structure for implement | achieving the light emission part 15 by the 1st Embodiment of this invention. It is sectional drawing which shows an example in case a laser beam and infrared rays are each light-emitted from the laser beam irradiation part 316 and the infrared irradiation part 101 by the 1st Embodiment of this invention. It is sectional drawing which shows another example in case a laser beam and infrared rays are each light-emitted from the laser beam irradiation part 316 and the infrared irradiation part 101 by the 1st Embodiment of this invention. It is a figure which shows an example of the projection pattern formed with the infrared rays which the infrared irradiation part 101 of the portable terminal 10 by the 1st Embodiment of this invention irradiates. It is a block diagram which shows the structure of the portable terminal 10 by the 1st Embodiment of this invention. It is a block diagram which shows an example of a structure of the image display apparatus 20 by the 1st this embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the portable terminal 10 by the 1st Embodiment of this invention. It is a figure which shows an example of the operation example at the time of transmitting image data from the portable terminal 10 to the image display apparatus 20 by the 1st Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the image display apparatus 20 by the 1st Embodiment of this invention. It is a figure which shows an example of the output method of the image data to the big screen display part 401 of the image display apparatus 20 by the 1st Embodiment of this invention. It is a figure which shows an example of the method of outputting image data to the screen 21 of the image display apparatus 20 by the 2nd Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the portable terminal 10 by the 2nd Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the image display apparatus 20 by the 2nd Embodiment of this invention. It is a sequence diagram which shows an example of the flow of a process between the portable terminal 10 and the image display apparatus 20 by the modification of the 2nd Embodiment of this invention. It is a figure for demonstrating an example of the process between the portable terminal 10 and the image display apparatus 20 by the 3rd Embodiment of this invention. It is a figure for demonstrating another example of the process between the portable terminal 10 and the image display apparatus 20 by the 3rd Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the portable terminal 10 by the 3rd Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the portable terminal 10a by the 3rd Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the image display apparatus 20 by the 3rd Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the portable terminal 10 by the 3rd Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the image display apparatus 20 by the 3rd Embodiment of this invention. It is a sequence diagram which shows an example of the flow of a process between the portable terminal 10 and the image display apparatus 20 by the 4th Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the image display apparatus 20 by the 4th Embodiment of this invention. It is a flowchart which shows an example of the flow of a process of the portable terminal 10 by the 4th Embodiment of this invention. It is a figure which shows the structure of the wireless adapter 1000 by the 5th Embodiment of this invention. It is a figure which shows an example of the attachment method to the television receiver of the wireless adapter 1000 by the 5th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Portable terminal, 14 ... Screen, 15 ... Light emission part, 20 ... Image display apparatus, 21 ... Screen, 101 ... Infrared irradiation part, 102 ... Laser light irradiation part , 103: Infrared irradiation unit mounting unit, 104: Laser beam irradiation unit mounting unit, 105 ... Outer frame, 301 ... Mobile terminal operation unit, 302 ... Mobile terminal display unit, 303 ... Display image creation unit 304: Mail transmission processing unit 305 ... Network communication unit 306 ... Additional data acquisition processing unit 307 ... Additional data transmission unit 308: Image operation information transmission 309... Image data transmitting unit 310... Image data holding unit 311... Image data synthesizing unit 312... Transmission / reception processing unit 313.・ Infrared light receiver, 315 ・ ・Infrared irradiation unit, 316 ... laser beam irradiation unit, 401 ... large screen display unit, 402 ... received image data holding unit, 403 ... display image creation unit, 404 ... received additional data holding unit 405: Image operation information reception processing unit, 406: Image data reception processing unit, 407: Additional data reception processing unit, 408: Additional data return processing unit, 409: First transmission / reception processing 410, second transmission / reception processing unit, 411 ... third transmission / reception processing unit, 412 ... first infrared irradiation unit, 413 ... first infrared light receiving unit, 414 ... second infrared irradiation. , 415... Second infrared light receiving unit, 416... Third infrared irradiation unit, 417.
1000 ... wireless adapter, 1001 ... casing, 1002 ... cable part, 1011a-1011c ... condensing lens

Claims (10)

An invisible wireless signal irradiating unit that emits an invisible wireless signal;
A visible light irradiation unit that irradiates visible light that forms a projection pattern at the irradiation destination;
A portable terminal, wherein a boundary of an irradiation range at an irradiation destination of the invisible wireless signal is indicated by the projection pattern.   The portable terminal according to claim 1, wherein the visible light irradiation unit narrows an irradiation range of the visible light at an irradiation destination to be smaller than an irradiation range of the invisible wireless signal at the irradiation destination. An invisible wireless signal irradiating unit that emits an invisible wireless signal;
A visible light irradiating unit that irradiates visible light provided in a direction opposite to the direction in which the invisible wireless signal irradiating unit irradiates the invisible wireless signal rather than the invisible wireless signal irradiating unit;
An optical path for visible light irradiated by the visible light irradiation unit is provided in a peripheral portion of the invisible wireless signal irradiation unit as viewed from a direction in which the invisible wireless signal irradiation unit emits an invisible wireless signal. Mobile device.   The portable terminal according to claim 3, wherein the optical path is at least an optical path in a vertical direction or a horizontal direction in a front view from the irradiation direction of the invisible wireless signal.   The portable terminal according to claim 3, wherein the optical path is at least an optical path in the vertical and horizontal directions in a front view from the irradiation direction of the invisible wireless signal.   The portable terminal according to claim 3, wherein the optical path is an optical path that irradiates on or within a boundary of an irradiation range of the invisible wireless signal in a front view from the irradiation direction of the invisible wireless signal. An operation unit for receiving the first or second instruction;
A transmission processing unit that transmits data using the invisible wireless signal irradiation unit;
When the operation unit receives a first instruction, the visible light irradiation unit starts visible light irradiation, and when the operation unit receives a second instruction, the transmission processing unit starts data transmission. A control unit that terminates the irradiation of visible light by the visible light irradiation unit when the transmission processing unit ends the transmission of data;
The mobile terminal according to any one of claims 1 to 6, further comprising:   The said control part changes the irradiation time per unit time of the visible light which the said visible light irradiation part irradiates according to whether the said operation part received the 2nd instruction | indication, It is characterized by the above-mentioned. The portable terminal as described in.   The said control part changes the irradiation time per unit time of the visible light which the said visible light irradiation part irradiates according to the speed which the said transmission process part transmits data, The Claim 7 or 8 characterized by the above-mentioned. Mobile devices. Irradiate the invisible wireless signal with the invisible wireless signal irradiation unit,
By irradiating the visible light irradiation unit with visible light that forms a projected pattern at the irradiation destination,
An irradiation range instructing method, wherein a boundary of an irradiation range at an irradiation destination of the invisible wireless signal is indicated by the projection pattern.

Images