JP4149844B2 - Electronic device with optical communication function, control method thereof, control program thereof, and optical communication device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an electronic device with an optical communication function such as a portable terminal device for performing data communication by wireless optical communication using light such as infrared rays., Its control method, its control program, and optical communication apparatus for optical communication with electronic equipment with optical communication functionIt is about.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, electronic devices with an optical communication function that perform data communication by wireless optical communication as described above, that is, optical communication using an optical fiber as an optical signal transmission path without using an optical fiber, are disclosed in Patent Documents 1 and 2 below, for example. Is known by. Then, in order to transfer data from such an electronic device to a network such as a LAN, optical communication for transferring data from the electronic device to the optical coupler unit, which is a wireless optical communication device connected to the network, by optical communication. The system is known.
[0003]
In this optical communication system, after parallel data is converted into serial data in an electronic device, it is modulated by a predetermined method by turning on / off a light emitting element such as an infrared LED and transmitted as signal light, and this is transmitted to the optical coupler unit side. Data is received by a light receiving element such as a provided phototransistor, received as an electrical signal, demodulated, and then serial / parallel converted, thereby enabling data transfer to the optical coupler unit. Further, data is transferred from the optical coupler unit to the network.
[0004]
Further, by providing a light receiving element on the electronic device side and a light emitting element on the optical coupler unit side, bidirectional optical communication can be performed. This bidirectional optical communication function is generally used to perform authentication before transfer, a retransmission request for garbled data during transfer, and the like according to a communication control communication protocol.
[0005]
[Patent Document 1]
JP-A-8-242205 (FIGS. 1 to 5)
[Patent Document 2]
Japanese Patent Laid-Open No. 11-284577 (FIGS. 1 and 4)
[0006]
[Problems to be solved by the invention]
By the way, in general, it is difficult for a wireless optical communication system to intercept communication illegally compared to a wireless communication system using radio waves. This is because the directivity of light is narrower than that of radio waves, the reachable distance is short, and the transmission path can be easily divided by a shield, so an antenna is installed in the vicinity of the communication device on the transmission side like radio waves. This is because the communication contents cannot be received simply by doing.
[0007]
However, in a wireless optical communication system, signal light can be intercepted as long as it travels through the air with a certain extent. For example, in the IrDA standard, the signal light emitted from the infrared LED spreads in a ± 15 ° conical shape and can communicate with a device placed at a maximum distance of about 1 m. This provides the user with the merit that even if the optical communication devices are positioned somewhat rough, communication can be performed without any problem as long as the signal lights from the other party are arranged in a conical space. However, a malicious person guides the signal light such as a phototransistor or a reflecting mirror to the light receiving element arranged outside the space as a means for intercepting in the space where the signal light spreads in a conical shape. If an optical element is inserted, communication can be intercepted.
[0008]
That is, in the optical communication system that performs wireless optical communication between the electronic device with an optical communication function and the optical coupler unit described above, unless the electronic device and the optical coupler unit are arranged in close contact with each other, There is a possibility that a means for eavesdropping is inserted into the space to be intercepted for communication.
[0009]
In the optical communication system, the optical coupler unit is connected to a specific network such as a LAN, and data from an electronic device with an optical communication function is originally transferred only within the specific network. However, by preparing a fake optical coupler unit connected to another network by a malicious person and arranging it so that it can perform optical communication with the electronic device instead of the regular optical coupler unit, It is also conceivable to steal the transmitted data by transferring it to another network.
[0010]
  Accordingly, an object of the present invention is to provide an electronic device with an optical communication function of the type described above., Its control method, its control program, and optical communication apparatus for optical communication with electronic equipment with optical communication functionThe present invention provides a configuration capable of preventing the above-described problems and improving the security of optical communication.
[0011]
[Means for Solving the Problems]
  In order to solve the above problems, the present invention(Claim 1)According to
  In electronic devices with optical communication functions,
  Optical communication means for performing data communication by wireless optical communication, and transmitting and transmitting signal light so as to spread a predetermined angle toward one direction;
  An imaging unit that electronically captures an image in a range substantially the same as a range in which the signal light from the optical communication unit spreads in the same direction as the one direction;
  When there is a change in an image photographed by the imaging means during optical communication by the optical communication means, a configuration having control means for performing control to interrupt optical communication is adopted.
  According to the present invention (Claim 2),
  Decoding means for decoding the code when a code of a predetermined format is included in the image photographed by the imaging means;
  Storage means for storing identification information of a communication device of a regular communication partner;
  Immediately before the start of optical communication by the optical communication means, the code is included in an image photographed by the imaging means, and information on the result of decoding the code by the decoding means is stored in the storage means. A configuration having a control means for controlling to start optical communication only when the identification information matches is adopted.
  According to the present invention (Claim 3),
  The optical communication means and the imaging means are arranged in the vicinity of each other facing the same surface,
  Image analysis means for analyzing an image taken by the imaging means immediately before the start of optical communication by the optical communication means to determine whether or not the optical communication means and the imaging means are in close contact with a communication partner optical communication device; Have
  Only when it is determined that the image analysis unit is not in close contact, the control unit performs the control during the optical communication.
  Moreover, according to this invention (Claims 5-10), the control method of the electronic device with an optical communication function corresponding to the structure of the electronic device with an optical communication function concerning the said this invention (Claims 1-3), and its control Adopted program structure.
  Furthermore, according to the present invention (invention 11), there is provided an optical communication apparatus for performing optical communication with the optical communication means of the electronic device with an optical communication function according to the present invention (invention 2).
  A configuration is adopted in which a code of a predetermined format indicating identification information of the optical communication device is displayed on the surface on which the light receiving means for receiving the signal light from the optical communication means is arranged.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. Here, an embodiment in a portable terminal device with an infrared communication function for performing data communication by wireless infrared communication is shown.
[0013]
[First Embodiment]
A first embodiment of the present invention will be described with reference to FIGS. First, FIG. 1 is a block diagram showing the configuration of the mobile terminal device 12 of this embodiment whose appearance is shown in FIG.
[0014]
The CPU 1 uses the RAM 2 as a work area and a storage area for various data processing and temporary storage, and controls the entire portable terminal device 12 according to a control program stored in the ROM 3.
[0015]
The keyboard 4 is one of input I / Fs (interfaces) of the mobile terminal device 12, and various data are input by an operator's operation, and instructions from the operator are transmitted to the CPU 1.
[0016]
The touch panel 5 is also an input I / F, and input is performed by an operator's touch operation. The touch panel 5 is made of a transparent material, and is arranged in close contact with the surface of the LCD 6 described later on the upper surface of the main body of the mobile terminal device 12 shown in FIG. It is designed to correspond one-on-one with coordinates. For this reason, for example, when an operator selects a button or switch displayed on the LCD 6 and performs input, the operator only has to press a desired button or switch over the touch panel 5 and the CPU 1 is selected. The input of the touch panel 5 can be recognized by specifying buttons and switches.
[0017]
The LCD 6 not only displays virtual buttons and switches in combination with the touch panel 5, but also displays messages, images, etc., and conveys information to the operator.
[0018]
The optical I / F 7 is an interface that performs optical communication (infrared communication) with an optical coupler unit 20 (see FIG. 3) to be described later in order to transfer data collected by the portable terminal device 12 to a host computer or the like. Consists of a phototransistor, an infrared LED, and a drive circuit thereof. As shown in FIG. 2, the optical I / F 7 is disposed facing the front end surface of the mobile terminal device 12.
[0019]
The printer 8 prints characters and images according to instructions from the CPU 1.
[0020]
The camera unit 9 is an imaging unit that electronically captures an image of the barcode or two-dimensional code that the mobile terminal device 12 captures. An image sensor such as a CCD or CMOS, a lens, an aperture, a shutter, or the like It is comprised by the optical apparatus. As shown in FIG. 2, the camera unit 9 faces the distal end surface of the mobile terminal device 12 and is disposed in the vicinity of the optical I / F 7.
[0021]
The decoder 10 analyzes the image data output from the camera unit 9, and if a bar code or a two-dimensional code is included in the image, the decoder 10 cuts out the image of the code and encodes the character encoded according to the code standard Decodes the string and outputs the string.
[0022]
The image data output from the camera unit 9 can be directly transferred to the CPU 1 without going through the decoder 10. In this case, the CPU 1 can handle the image itself, and can perform various image processing using the image processing program in the ROM 3 and using the work area in the RAM 2 for work.
[0023]
The image comparison unit 11 is one of the image processing units in which the CPU 1 realizes processing functions by software using the image processing program in the ROM 3 and the RAM 2 as described above, and a plurality of images stored in the RAM 2 as will be described later. Are compared to determine whether the contents are the same.
[0024]
Next, FIG. 3 shows the external appearance of the state where the mobile terminal device 12 is in optical communication with the optical coupler unit 20.
[0025]
The optical coupler unit 20 is provided with an optical I / F 21 similar to the optical I / F 7 of the mobile terminal device 12 on the front surface. During optical communication, the mobile terminal device 12 and the optical coupler unit 20 are connected as shown in FIG. It is necessary to arrange the optical I / Fs 7 and 21 so as to face each other.
[0026]
The optical I / F 21 receives (receives) an optical (infrared) signal from the optical I / F 7 and converts it into an electrical signal. The electrical signal is analyzed for a protocol by a communication control circuit including a CPU, a ROM, a RAM, and the like (not shown) built in the optical coupler unit 20, and the contained data is extracted. Further, the data is converted in accordance with the TCP / IP protocol, transferred over a LAN (not shown) via the LAN cable 22, and transferred to a host computer (not shown) connected to the LAN.
[0027]
Conversely, data sent from the LAN to the optical coupler unit 20 via the LAN cable 22 is processed by the communication control circuit of the unit 20 and converted into data for optical communication. It is transmitted to the optical I / F 7 as a signal.
[0028]
The indicator 23 provided in the optical coupler unit 20 is formed of an LED, and notifies the operator of signals on the LAN to which the LAN cable 22 is connected, collision status, and the like. In addition, the indicator 23 is arrange | positioned in the place which cannot be seen from the portable terminal device 12 side in side surfaces other than the front surface in which the optical I / F 21 was provided in the optical coupler unit 20.
[0029]
In addition, an identification code 24 is printed and displayed near the optical I / F 21 in front of the optical coupler unit 20. The identification code 24 is obtained by encoding an ID (identification information) assigned to the optical coupler unit 20 in order to optically identify the optical coupler unit 20 as a regular communication partner of the mobile terminal device 12. Although shown as a two-dimensional code in FIG. 3, it may be a bar code or another code. It is assumed that the ID information is registered and stored in the RAM 2 of the mobile terminal device 12 in advance.
[0030]
The optical I / F 7 of the mobile terminal device 12 has a conical shape toward the optical axis direction, which is one direction perpendicular to the distal end surface of the mobile terminal device 12, as indicated by reference numeral 25 in FIG. Transmission is performed by emitting light so as to spread a predetermined angle. If the mobile terminal device 12 and the optical coupler unit 20 are arranged as shown in FIG. 3, the signal light 25 is received by the optical I / F 21 of the optical coupler unit 20.
[0031]
The camera unit 9 of the mobile terminal device 12 has an optical axis direction that is the same as the optical axis direction of the optical I / F 7, and the angle of view is the signal light of the optical I / F 7 as indicated by reference numeral 26. The angle is substantially the same as the 25 spread angle. That is, the camera unit 9 can capture an image in a range substantially the same as the range in which the signal light 25 spreads in the optical axis direction. If the mobile terminal device 12 and the optical coupler unit 20 are arranged as shown in FIG. 3, the camera unit 9 can capture images of the front side of the optical coupler unit 20 and its surroundings in a range substantially the same as the range of the signal light 25. it can.
[0032]
Next, FIG. 4 shows that while the mobile terminal device 12 is in optical communication with the optical coupler unit 20, a malicious person is in the vicinity of the optical coupler unit 20 from the optical I / F 7 of the mobile terminal device 12. A state is shown in which a mirror 30 is inserted into a space where the signal light 25 is spread and transmitted, and transmission from the mobile terminal device 12 is intercepted. By inserting the mirror 30 in this way, a part of the signal light (infrared rays) from the optical I / F 7 is reflected as shown as a light beam 31 and guided to the optical coupler unit 32 for interception, and the portable terminal device The transmission from 12 is intercepted. A portion of the signal light 25 received by the optical I / F 21 of the optical coupler unit 20 is not blocked by the mirror 30, and signal light (not shown) from the optical coupler unit 20 is transmitted to the optical I / F 7 of the portable terminal device 12. As long as the light receiving portion is not blocked, the optical communication itself is normally performed. Interception can also be performed by inserting an optical element such as a beam splitter or prism or a light receiving element such as a phototransistor instead of the mirror 30.
[0033]
Next, FIG. 5 shows an example of an image on the side of the optical coupler unit 20 taken by the camera unit 9 of the mobile terminal device 12 in a state where the mobile terminal device 12 and the optical coupler unit 20 are arranged facing each other as shown in FIG. Show. Since the angle of view of the camera unit 9 is as shown by reference numeral 26 in FIG. 3, the optical unit can be set as shown in FIG. 5 by appropriately setting the distance between the portable terminal device 12 and the optical coupler unit 20. An image including the identification code 24 is taken on the front side where the 20 optical I / Fs 21 are provided and the surrounding image.
[0034]
In this case, whether or not the optical coupler unit 20 is a legitimate communication partner depends on whether or not the information obtained by decoding the identification code 24 matches the ID of the legitimate communication partner registered in the RAM 2 described above (false). It can be judged) Therefore, in the present embodiment, in the mobile terminal device 12, the CPU 1 makes this determination immediately before the start of optical communication, and controls so as to start optical communication only when it is determined as a regular communication partner. This control is performed as follows according to the procedure shown in the flowchart of FIG. 6 according to the control program stored in the ROM 3.
[0035]
That is, immediately before the optical communication by the optical I / F 7 is started, the camera unit 9 is driven to capture an image on the communication partner optical coupler unit side, and the decoder 10 analyzes the captured image, and the identification code 24 and If a code of the same format (for example, a two-dimensional code or a barcode) is included, a process of cutting it out and decoding it is performed (step S1).
[0036]
Next, the analysis result of the decoder 10 is examined, and it is determined whether or not the photographed image includes a code having the same format as the identification code 24 (step S2). If included, information on the result of decoding the code. Is matched with the ID of the regular communication partner registered in the RAM 2 (step S3). If they match, the optical communication is started (step S4). Note that the control of FIG. 8 described later is performed during optical communication.
[0037]
On the other hand, if the photographed image does not contain the above code in step S2 and if the information obtained as a result of decoding the code in step S3 does not match the registered regular ID, it is malicious. However, there is a possibility that an optical coupler unit of a false communication partner is arranged opposite to the portable terminal device 12, and optical communication is being attempted. Therefore, an error display for notifying the operator of the fact is made on the LCD 6 (step S5) The process is terminated without performing optical communication.
[0038]
Next, FIG. 7 shows the camera unit of the mobile terminal device 12 when a malicious person inserts the mirror 30 in the range in which the signal light 25 is transmitted as shown in FIG. 9 shows an example of an image taken on the side of the optical coupler unit 20 taken by No. 9. Since the range of the angle of view of the camera unit 9 substantially coincides with the range in which the signal light 25 is spread and transmitted, if the mirror 30 is inserted in the range of the signal light 25, the optical coupler that is photographed as shown in FIG. The image of the mirror 30 is included in the image on the unit 20 side.
[0039]
Therefore, when the mirror 30 is inserted as shown in FIG. 4 from the state of FIG. 3 during optical communication, the image taken by the camera unit 9 changes as shown in FIGS. If there is a change in the image photographed by the unit 9, there is a possibility that an object such as the mirror 30 has been inserted within the range in which the signal light 25 travels due to unauthorized interception, that is, unauthorized interception may be performed. It can be judged that there is sex.
[0040]
Therefore, in the present embodiment, in the mobile terminal device 12, the CPU 1 makes this determination during optical communication, and controls to interrupt optical communication when it is determined that there is a possibility of unauthorized interception. This control is performed as follows according to the procedure shown in the flowchart of FIG. 8 according to the control program stored in the ROM 3.
[0041]
That is, first, the camera unit 9 is driven immediately before optical communication is actually performed to capture an image on the optical coupler unit side of the communication partner (step S11), and the image data is stored in the RAM 2 as first image data. (Step S12).
[0042]
Next, the optical I / F 7 is opened, that is, initialized to be usable (step S13).
[0043]
Next, after one packet of data is transmitted to the other optical coupler unit by the optical I / F 7 (step S14), the camera unit 9 captures the image again (step S15), and the captured image data is converted into the second image. Data is stored in the RAM 2 (step S16).
[0044]
Next, the image comparison unit 11 compares the data of the first image and the second image in the RAM 2 to determine whether or not they are the same (step S17). This comparison method is the simplest method in which image data is simply compared byte by byte as image binary data. However, two images are taken into account in consideration of imaging noise, lighting flicker, etc. of the camera unit 9 itself. It is more desirable to use a comparison logic that determines that the images are the same when the difference between them is very small.
[0045]
If both are the same as a result of this comparison, it is considered that there is no means for intercepting communication such as a mirror within the range of the angle of view 26 (within the range in which the signal light 25 spreads), and the step Proceed to S18.
[0046]
In step S18, it is determined whether or not the communication of all packets has been completed. If not, the process returns to step S14 to repeat the processes in step S14 and subsequent steps. The processes in steps S14 to S18 are repeated until the first and second images become different in step S17 or until communication of all packets is completed in step S18. Note that the data of the second image that is periodically and sequentially captured by this repetition is overwritten on the second image data that was previously captured on the RAM 2.
[0047]
If all packets have been communicated in step S18, the optical I / F 7 is closed to terminate the optical communication (step S20), and the process is terminated.
[0048]
On the other hand, if the result of comparing the first and second images in step S17 is that they are different, that is, if the image captured by the camera unit 9 has changed, unauthorized communication is performed within the range of the angle of view 26. It is determined that there is a possibility that an object such as a mirror for interception exists, and the process proceeds to step S19.
[0049]
In step S19, since there is a possibility that the communication is intercepted illegally, the fact that the communication is interrupted is displayed on the LCD 6, and then in step S20, the optical I / F 7 is closed to interrupt the optical communication, and the process is terminated. .
[0050]
According to the portable terminal device 12 of the present embodiment as described above, a code of the same format as the identification code 24 is included in the image of the communication partner optical coupler unit imaged by the camera unit 9 immediately before the start of optical communication. The optical communication is started only when the information of the result of decoding included therein matches the ID of the regular communication partner stored in the RAM 2, that is, the optical coupler unit of the communication partner is a regular communication partner. Since optical communication is started only in some cases, it is possible to prevent data from being stolen by performing optical communication with a false communication partner optical coupler unit.
[0051]
In addition, the camera unit 9 periodically captures an image on the communication partner side during optical communication, and when there is a change in the image, a mirror or the like for illegal interception is transmitted within the signal light 25 spread. Since it is determined that there is a possibility that it has been inserted into the optical communication and the optical communication is interrupted, unauthorized interception can be prevented in advance.
[0052]
In the present embodiment, when an illegal intercepting mirror or the like is arranged in a range where the signal light 25 is spread and transmitted before the start of optical communication, this cannot be detected. However, when performing optical communication, an operator always performs an operation of placing the mobile terminal device 12 facing the optical coupler unit 20 and performs an operation to start communication. Of course, the operator notices this when it is arranged in front of the optical coupler unit 20. And since suspicious things are removed, there is no problem of interception.
[0053]
[Second Embodiment]
In the above-described first embodiment, it has been described that optical communication is performed in a state where the mobile terminal device 12 and the optical coupler unit 20 are arranged to face each other with a certain distance as shown in FIG. However, optical communication can also be performed by placing the mobile terminal device 12 and the optical coupler unit 20 in close contact so that the optical I / Fs 7 and 21 are in close contact with each other. That is, depending on the operator, there are cases where the mobile terminal device 12 and the optical coupler unit 20 are arranged at a distance, or in close contact with each other. When closely arranged, it is not possible to intercept by inserting a mirror or the like between the two during optical communication. If they are separated to insert a mirror or the like during optical communication, a communication error occurs and interception cannot be performed. Therefore, when arranged closely, it is not necessary to perform the control shown in FIG. 8 for preventing interception during optical communication.
[0054]
Considering this point, the control of FIG. 6 described above performed immediately before the start of optical communication by the CPU 1 may be changed as shown in FIG. In the control of FIG. 9, step S6 different from steps S1 to S5 common to steps S1 to S5 of FIG. 6 is added. Hereinafter, description of common parts is omitted, and only different points will be described.
[0055]
If the CPU 1 determines in step S2 that the communication partner optical coupler unit side image captured by the camera unit 9 does not contain the same type code of the identification code 24, the process proceeds to step S6.
[0056]
In step S6, the brightness of the entire image captured by the camera unit 9 is checked to determine whether or not the entire image is black. Here, when the mobile terminal device 12 and the optical coupler unit 20 are in close contact (the optical I / Fs 7 and 21 are in close contact), the camera unit 9 is also in close contact with the front surface of the optical coupler unit 20. External light does not enter, and the entire photographed image becomes black. Therefore, whether or not the optical I / F 7 of the mobile terminal device 12 and the camera unit 9 are in close contact with the front surface of the optical coupler unit 20 can be determined based on whether or not the entire captured image is black.
[0057]
If it is determined that the entire image is black and in close contact, the process proceeds to step S4 and optical communication is started. However, the control shown in FIG. 8 for preventing interception during the optical communication is not performed.
[0058]
If the photographed image includes a code having the same format as the identification code 24 and the information obtained as a result of decoding it matches the ID of the regular communication partner stored in the RAM 2, the steps S2, S3 and S3 are performed. In S4, the optical communication is started. In this case, since the mobile terminal device 12 and the optical coupler unit 20 are separated from each other, the control shown in FIG. 8 for preventing interception is performed during the optical communication.
[0059]
On the other hand, if it is determined in step S6 that the entire captured image is not black and the mobile terminal device 12 and the optical coupler unit 20 are not in close contact (separated), the process proceeds to step S5, and the image includes a code. Therefore, the error display described above is performed on the LCD 6, and the process is terminated without performing optical communication.
[0060]
According to the second embodiment as described above, it is possible to appropriately cope with the case where the mobile terminal device 12 is disposed in close contact with the communication partner optical coupler unit.
[0061]
In the present embodiment, when the mobile terminal device 12 is disposed in close contact with the optical coupler unit of the communication partner, it is determined whether the optical coupler unit is a regular communication partner based on the captured image of the camera unit 9. Although it is not possible to arrange closely, the operator who performs the work will look closely at the optical coupler unit, so it is intuitively determined whether it is a familiar regular communication partner. be able to.
[0062]
The embodiment of the portable terminal device with an infrared communication function has been described above. However, the present invention can be applied to other electronic devices with an optical communication function and can also be applied to non-portable electronic devices. Of course, optical communication is not limited to infrared communication.
[0063]
As mentioned above, although embodiment of this invention was described, of course, the meaning and scope of this invention are not limited to what was demonstrated by embodiment. Examples of embodiments of the present invention are listed below.
[0064]
[Embodiment 1] Optical communication means for performing data communication by wireless optical communication, wherein the optical communication means emits and transmits signal light so as to spread a predetermined angle toward one direction;
An imaging unit that electronically captures an image in a range substantially the same as a range in which the signal light from the optical communication unit spreads in the same direction as the one direction;
An electronic apparatus with an optical communication function, comprising: control means for performing control to interrupt optical communication when an image photographed by the imaging means is changed during optical communication by the optical communication means.
[0065]
[Embodiment 2] Decoding means for decoding a code in a predetermined format in an image photographed by the imaging means;
Storage means for storing identification information of a communication device of a regular communication partner;
Immediately before the start of optical communication by the optical communication means, the code is included in an image photographed by the imaging means, and information on the result of decoding the code by the decoding means is stored in the storage means. The electronic device with an optical communication function according to the first embodiment, further comprising a control unit that controls to start optical communication only when the identification information matches.
[0066]
[Embodiment 3] The optical communication means and the imaging means are arranged in the vicinity of each other facing the same surface,
Image analysis means for analyzing an image taken by the imaging means immediately before the start of optical communication by the optical communication means to determine whether or not the optical communication means and the imaging means are in close contact with a communication partner optical communication device; Have
2. The electronic apparatus with an optical communication function according to claim 1, wherein the control means performs the control during the optical communication only when it is determined that the image analysis means is not in close contact.
[0067]
[Embodiment 4] The electronic device with an optical communication function according to any one of Embodiments 1 to 3, wherein the code is a two-dimensional code.
[0068]
[Embodiment 5] A method for controlling an electronic apparatus with an optical communication function having optical communication means for performing data communication by wireless optical communication and transmitting signal light so as to spread a predetermined angle toward one direction. And
During optical communication by the optical communication means, an image of an image in an approximately same range as the range in which the signal light from the optical communication means spreads in the same direction as the one direction by an imaging means that electronically captures an image, A control method for an electronic device with an optical communication function, wherein control is performed to interrupt optical communication when the image is changed.
[0069]
[Embodiment 6] Immediately before the start of optical communication by the optical communication means, an image in a range substantially the same as the range in which the signal light from the optical communication means spreads in the same direction as the one direction is taken by the imaging means. When the photographed image contains a code of a predetermined format, the code is decoded, and optical communication is performed only when the information of the result matches the identification information of the regular communication partner communication device stored in advance. The control method of the electronic device with an optical communication function according to the fifth embodiment, wherein the control is performed so as to start.
[0070]
[Embodiment 7] Immediately before the start of optical communication by the optical communication means, the image pickup means captures an image in a range substantially the same as the range in which the signal light from the optical communication means spreads in the same direction as the one direction. , Analyzing the photographed image to determine whether the optical communication means and the imaging means are in close contact with the communication partner optical communication device, and only when it is determined that the optical communication means is not in close contact, control during the optical communication is performed The control method of the electronic device with an optical communication function according to the fifth embodiment, wherein the method is performed.
[0071]
[Embodiment 8] A control program for an electronic device with an optical communication function having optical communication means for performing data communication by wireless optical communication and transmitting the signal light so as to spread a predetermined angle toward one direction. And
During optical communication by the optical communication means, an image of an image in an approximately same range as the range in which the signal light from the optical communication means spreads in the same direction as the one direction by an imaging means that electronically captures an image, A control program for an electronic device with an optical communication function, comprising: a control procedure for controlling to interrupt optical communication when the image is changed.
[0072]
[Embodiment 9] Immediately before the start of optical communication by the optical communication means, the image pickup means captures an image in a range substantially the same as the range in which the signal light from the optical communication means spreads in the same direction as the one direction. When the photographed image contains a code of a predetermined format, the code is decoded, and optical communication is performed only when the information of the result matches the identification information of the regular communication partner communication device stored in advance. The control program for an electronic device with an optical communication function according to the eighth embodiment, comprising a control procedure for controlling to start.
[0073]
[Embodiment 10] Immediately before the start of optical communication by the optical communication unit, an image in a range substantially the same as the range in which the signal light from the optical communication unit spreads in the same direction as the one direction is captured by the imaging unit. , Analyzing the photographed image to determine whether the optical communication means and the imaging means are in close contact with the communication partner optical communication device, and only when it is determined that the optical communication means is not in close contact, control during the optical communication is performed The control program for an electronic device with an optical communication function according to the eighth embodiment, comprising a control procedure for performing the control.
[0074]
[Embodiment 11] An optical communication apparatus that performs optical communication with optical communication means of an electronic device with an optical communication function according to Embodiment 2,
An optical communication apparatus characterized in that a code of a predetermined format indicating identification information of the optical communication apparatus is displayed on a surface on which a light receiving means for receiving signal light from the optical communication means is arranged.
[0075]
【The invention's effect】
As is apparent from the above description, according to the present invention, in an electronic device with an optical communication function, a signal emitted from an optical communication means so as to spread a predetermined angle toward one direction for transmission during optical communication. Since an image of the same range as the range in which the light spreads is electronically taken and the image changes, the optical communication is interrupted, so an optical element such as a mirror or a light receiving element in the range in which the signal light spreads It is possible to prevent the communication from being intercepted illegally due to the insertion of. In addition, immediately before the start of optical communication, when a code of a predetermined format is included in the above image, the information obtained as a result of decoding the code matches the identification information of the communication device of the regular communication partner stored in advance. Since the optical communication is started only at the time, it is possible to prevent the data from being stolen by performing the optical communication with the false communication partner communication device. Therefore, an excellent effect that the security of optical communication can be remarkably improved is obtained.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of a mobile terminal device with an infrared communication function according to a first embodiment of the present invention.
FIG. 2 is a perspective view showing an appearance of the portable terminal device.
FIG. 3 is a perspective view showing a state in which the mobile terminal device performs optical communication with the optical coupler unit.
FIG. 4 is a perspective view showing a state in which communication is illegally intercepted by insertion of a mirror that reflects signal light during optical communication.
FIG. 5 is an explanatory diagram showing an example of an image taken by the camera unit of the mobile terminal device on the optical coupler unit side of the communication partner.
FIG. 6 is a flowchart showing a control procedure for starting optical communication only when a communication partner optical coupler unit is a regular one in a portable terminal device.
FIG. 7 is an explanatory diagram illustrating an example of an image obtained by capturing an optical coupler unit side of a communication partner in a state where an intercepting mirror is inserted in the camera unit of the mobile terminal device.
FIG. 8 is a flowchart illustrating a control procedure for preventing unauthorized interception during optical communication in the mobile terminal device.
FIG. 9 is a flowchart showing a control procedure for starting optical communication only when the communication partner optical coupler unit is a regular one and in close contact with the communication partner in the portable terminal device of the second embodiment. FIG.
[Explanation of symbols]
1 CPU
2 RAM
3 ROM
4 Keyboard
5 Touch panel
6 LCD
7 Hikari I / F
8 Printer
9 Camera unit
10 Decoder
11 Image comparison unit
12 Mobile terminal device
20 Optical coupler unit
21 Hikari I / F
24 Identification code
25 Signal light from optical I / F7 (infrared)
26 Angle of view of camera unit
30 Mirror for interception
32 Optical coupler unit for interception

Claims (11)

Optical communication means for performing data communication by wireless optical communication, and transmitting and transmitting signal light so as to spread a predetermined angle toward one direction;
An imaging unit that electronically captures an image in a range substantially the same as a range in which the signal light from the optical communication unit spreads in the same direction as the one direction;
An electronic apparatus with an optical communication function, comprising: control means for performing control to interrupt optical communication when an image photographed by the imaging means is changed during optical communication by the optical communication means. Decoding means for decoding the code when a code of a predetermined format is included in the image photographed by the imaging means;
Storage means for storing identification information of a communication device of a regular communication partner;
Immediately before the start of optical communication by the optical communication means, the code is included in an image photographed by the imaging means, and information on the result of decoding the code by the decoding means is stored in the storage means. 2. The electronic device with an optical communication function according to claim 1, further comprising a control unit that controls to start optical communication only when the identification information matches. The optical communication means and the imaging means are arranged in the vicinity of each other facing the same surface,
Image analysis means for analyzing an image taken by the imaging means immediately before the start of optical communication by the optical communication means to determine whether or not the optical communication means and the imaging means are in close contact with a communication partner optical communication device; Have
2. The electronic device with an optical communication function according to claim 1, wherein the control unit performs control during the optical communication only when it is determined that the image analysis unit is not in close contact. The electronic device with an optical communication function according to any one of claims 1 to 3, wherein the code is a two-dimensional code. Data communication is performed by wireless optical communication, and the transmission is a method of controlling an electronic device with an optical communication function having an optical communication means that emits signal light so as to spread a predetermined angle toward one direction,
During optical communication by the optical communication means, an image of an image in an approximately same range as the range in which the signal light from the optical communication means spreads in the same direction as the one direction by an imaging means that electronically captures an image, A control method for an electronic device with an optical communication function, wherein control is performed to interrupt optical communication when the image is changed. Immediately before the start of optical communication by the optical communication means, an image in a range substantially the same as the range in which the signal light from the optical communication means spreads in the same direction as the one direction is taken by the imaging means, and the captured image Control to start optical communication only when the code of a predetermined format is included in the code and the code is decoded and the result information matches the identification information of the communication device of the regular communication partner stored in advance. The method of controlling an electronic device with an optical communication function according to claim 5. Immediately before the start of optical communication by the optical communication means, an image in a range substantially the same as the range in which the signal light from the optical communication means spreads in the same direction as the one direction is taken by the imaging means, and the captured image And determining whether or not the optical communication means and the imaging means are in close contact with the optical communication device of the communication partner, and performing control during the optical communication only when it is determined that they are not in close contact with each other The control method of the electronic device with an optical communication function according to claim 5. Data communication is performed by wireless optical communication, and transmission is a control program for an electronic device with an optical communication function having optical communication means that performs signal light emission so as to spread a predetermined angle toward one direction,
During optical communication by the optical communication means, an image of an image in an approximately same range as the range in which the signal light from the optical communication means spreads in the same direction as the one direction by an imaging means that electronically captures an image, A control program for an electronic device with an optical communication function, comprising: a control procedure for controlling to interrupt optical communication when the image is changed. Immediately before the start of optical communication by the optical communication means, the imaging means An image in a range approximately the same as the range in which the signal light from the optical communication means spreads in the same direction as the one direction is described, and the code is decoded when a code of a predetermined format is included in the captured image And a control procedure for controlling to start optical communication only when the information of the result matches the identification information of the communication device of the regular communication partner stored in advance. The control program of the electronic device with an optical communication function of description. Immediately before the start of optical communication by the optical communication means, an image in a range substantially the same as the range in which the signal light from the optical communication means spreads in the same direction as the one direction is taken by the imaging means, and the captured image And determining whether or not the optical communication means and the imaging means are in close contact with the optical communication device of the communication partner, and a control procedure for performing control during the optical communication only when it is determined that the optical communication means and the image pickup means are not in close contact with each other The control program for an electronic device with an optical communication function according to claim 8, comprising: An optical communication device that performs optical communication with optical communication means of the electronic device with an optical communication function according to claim 2,
An optical communication apparatus characterized in that a code of a predetermined format indicating identification information of the optical communication apparatus is displayed on a surface on which a light receiving means for receiving signal light from the optical communication means is arranged.

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