JP2005245596A - Antenna accommodating apparatus and antenna testing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize an antenna accommodating apparatus which enables a performance test of an antenna means such as an antenna for receiving to be easily performed and an antenna testing system using the antenna accommodating apparatus. <P>SOLUTION: The antenna testing system comprises the antenna accommodating apparatus 2 to accommodate the antennas 1a-1h for receiving which are subjects of the performance test and a testing apparatus 3 to perform the performance test of the antennas 1a-1h for receiving while the antennas 1a-1h for receiving are accommodated in the antenna accommodating apparatus 2. Accommodation sections 4a-4h which are formed corresponding to each of the antennas 1a-1h for receiving and testing signal transmitting sections 5a-5h which act by control from the testing apparatus 3 are disposed in the antenna accommodating apparatus 2 and the performance test of the antennas 1a-1h for receiving is performed by transmitting wireless signals for the test from the testing signal transmitting sections 5a-5h. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an antenna housing apparatus for housing antenna means and an antenna inspection system using the antenna housing apparatus.

  In recent years, swallowable capsule endoscopes have appeared in the field of endoscopes. This capsule endoscope is provided with an imaging function and a wireless communication function. Capsule endoscopes are peristaltic in the body cavity, for example, the stomach, small intestine, etc., after being swallowed from the patient's mouth for observation (examination) and before being spontaneously discharged from the human body. It has the function to move according to and to image sequentially.

  While moving in the body cavity, image data captured inside the body by the capsule endoscope is sequentially transmitted to the outside by wireless communication and received via a receiving antenna provided outside. Then, based on the received wireless signal, the data is reproduced by a receiving device provided outside the subject, whereby it is possible to acquire an in-vivo image of the patient. When the patient carries the receiving device having the wireless communication function and the memory function, the patient can freely act even during the period from swallowing the capsule endoscope until it is discharged. Thereafter, the doctor or nurse can make a diagnosis by displaying an organ image on the display based on the image data stored in the memory (see, for example, Patent Document 1).

  Here, since the capsule endoscope outputs a wireless signal while sequentially moving in the body cavity, the capsule endoscope system has a receiving antenna for receiving the wireless signal output from the capsule endoscope. In general, a plurality of structures are provided near the subject, for example, on the surface of the subject. Therefore, the conventional capsule endoscope system receives a radio signal by selecting a receiving antenna that is most suitable for reception according to the receiving strength at each receiving antenna, usually the receiving antenna with the highest receiving strength. It is possible to acquire an in-vivo image while maintaining good reception sensitivity.

  By the way, when the receiving antenna cannot perform its function due to disconnection or the like, it becomes impossible to acquire the body cavity image captured by the capsule endoscope. Therefore, in a general capsule endoscope system, it is necessary to check whether there is a failure of the receiving antenna or the like before a predetermined period elapses or before the capsule endoscope is introduced into the subject.

  For the performance test of the receiving antenna, for example, the receiving apparatus is driven with the receiving antenna equipped, and a dummy signal having the same frequency as the radio signal transmitted from the capsule endoscope is transmitted to the receiving antenna. . Since the transmitted dummy signal is input to the receiving device via the receiving antenna, it is determined whether the receiving level detected by the receiving device is higher than a predetermined threshold value. The presence or absence of a failure is detected.

Japanese Patent Laying-Open No. 2001-231186 (page 3, FIG. 1)

  However, when a conventional capsule endoscope system is provided with a plurality of receiving antennas outside the subject, there is a problem that handling at the time of performance inspection of the receiving antenna becomes complicated. Hereinafter, this problem will be described.

  As described above, switching of a plurality of receiving antennas by the receiving apparatus is performed by selecting a receiving antenna having the highest reception strength. Therefore, when a dummy signal is transmitted to all the receiving antennas at the same time during the performance inspection of the receiving antenna, only the receiving intensity at the specific receiving antenna having the strongest receiving intensity is monitored by the receiving apparatus. Thus, inspection cannot be performed for reception antennas other than the reception antenna having the maximum reception strength.

  Therefore, in the conventional capsule endoscope system, it is necessary to sequentially check each of a plurality of receiving antennas. That is, for example, with respect to a single receiving antenna, it is necessary to sequentially perform operations such as receiving a dummy signal in a state of being arranged in the vicinity of an output antenna that outputs a dummy signal for each receiving antenna. When the inspection is performed on the receiving antenna, the processing becomes very complicated.

  The present invention has been made in view of the above, and realizes an antenna housing apparatus and an antenna inspection system using the antenna housing apparatus that can easily perform performance inspection of antenna means such as a receiving antenna. For the purpose.

  In order to solve the above-described problems and achieve the object, an antenna accommodation apparatus according to claim 1 is an antenna accommodation apparatus that accommodates antenna means formed to be able to receive a radio signal, and accommodates the antenna means. And a test signal transmission unit that is disposed in the vicinity of the storage unit and transmits a radio signal for inspection to the antenna unit stored in the storage unit.

  According to the first aspect of the invention, since the antenna accommodating device is provided with the inspection signal transmitting means for transmitting the radio signal for inspection, the use of the antenna means is finished and the antenna accommodating device is still accommodated. Thus, the performance inspection of the receiving antenna can be performed.

  According to a second aspect of the present invention, there is provided the antenna accommodation apparatus according to the above invention, wherein there are a plurality of the antenna means to be accommodated, and a plurality of the accommodation means are arranged corresponding to the number of the antenna means, and the inspection signal transmission The means is further provided with a control means which is arranged in a plurality according to the plurality of accommodating means and sequentially selects and drives the plurality of inspection signal transmitting means.

  According to the second aspect of the present invention, since the inspection signal transmission means is provided corresponding to the plurality of antenna means, it is possible to sequentially transmit the inspection radio signals to the individual antenna means. Therefore, it is possible to prevent a wireless signal for inspection from being transmitted to a plurality of antenna means at a time, and an accurate performance inspection can be performed.

  According to a third aspect of the present invention, there is provided the antenna accommodating device according to the above invention, wherein the accommodating means includes a fixing means for fixing a positional relationship between the antenna means and the inspection signal transmitting means. .

  According to the third aspect of the present invention, since the fixing means for fixing the positional relationship between the antenna means and the inspection signal transmitting means when the antenna means is accommodated, the radio signal for inspection in the antenna means is provided. It is possible to suppress the fluctuation of the reception environment and perform the performance inspection in a stable environment.

  According to a fourth aspect of the present invention, there is provided the antenna accommodating device according to the above invention, wherein the antenna means has a wireless transmission function and is transmitted wirelessly from an in-subject introduction apparatus introduced into the subject during normal use. It has a function of receiving a signal, and the radio signal for examination includes the same signal pattern as the radio signal transmitted from the intra-subject introduction apparatus.

  According to a fifth aspect of the present invention, there is provided the antenna accommodating device according to the above invention, wherein the antenna means has an imaging function and a wireless transmission function and is introduced into the subject during normal use. It has a function of receiving a wireless signal including captured image data to be transmitted, and the wireless signal for inspection includes an image signal having a predetermined pattern output from an imaging unit that images a predetermined subject. It is characterized by.

  According to a sixth aspect of the present invention, there is provided an antenna inspection system comprising: an antenna accommodating device that accommodates a plurality of antenna means each configured to be able to receive a radio signal; and an inspection that performs performance inspection of the antenna means accommodated in the antenna accommodating device. An antenna inspection system comprising: a housing means for housing the antenna means; and an antenna means disposed in the vicinity of the housing means for testing the antenna means housed in the housing means. Inspection signal transmitting means for outputting a radio signal for use, wherein the inspection apparatus is connected via the antenna means and connected via the antenna means and electrically connected to the antenna means. And a signal processing means for performing a predetermined process on the inputted inspection signal.

  In the antenna inspection system according to claim 7, in the above invention, the inspection device functions as a reception device during normal use of the antenna means, and the signal processing means is received via the antenna means. A predetermined process is performed on the radio signal.

  The antenna inspection system according to claim 8 is characterized in that, in the above invention, the inspection apparatus further comprises display means for displaying the content of the signal processed by the signal processing means.

  According to a ninth aspect of the present invention, in the above-described invention, the antenna inspection system further includes a display device that visually displays image data based on the signal processed by the signal processing means.

  Since the antenna accommodating apparatus according to the present invention is configured to include the inspection signal transmitting means for transmitting a radio signal for inspection in the antenna accommodating apparatus, the use of the antenna means is finished and the antenna accommodating apparatus remains in the state accommodated in the antenna accommodating apparatus. There is an effect that the performance inspection of the receiving antenna can be performed.

  In addition, since the antenna accommodating apparatus according to the present invention has a configuration in which the inspection signal transmission unit is provided corresponding to the plurality of antenna units, it is possible to sequentially transmit a radio signal for inspection to each antenna unit. is there. Therefore, it is possible to prevent wireless signals for inspection from being transmitted to a plurality of antenna means at the same time, and it is possible to perform an accurate performance inspection.

  Further, since the antenna accommodation apparatus according to the present invention includes a fixing means for fixing the positional relationship between the antenna means and the inspection signal transmission means when accommodating the antenna means, the radio signal for inspection in the antenna means is provided. It is possible to suppress the fluctuation of the reception environment of the mobile phone and to perform a performance test in a stable environment.

  Hereinafter, an antenna inspection system which is the best mode for carrying out the present invention (hereinafter simply referred to as “embodiment”) will be described. Note that the drawings are schematic, and it should be noted that the relationship between the thickness and width of each part, the ratio of the thickness of each part, and the like are different from the actual ones. Of course, the part from which the relationship and ratio of a mutual dimension differ is contained.

  FIG. 1 is a schematic diagram showing the overall configuration of the antenna inspection system according to the present embodiment. As shown in FIG. 1, the antenna inspection system according to the present embodiment includes an antenna accommodating device 2 that accommodates receiving antennas 1 a to 1 h and a case where the receiving antennas 1 a to 1 h are accommodated in the antenna accommodating device 2. And an inspection device 3 for performing a performance inspection of the receiving antennas 1a to 1h.

  The receiving antennas 1a to 1h function as inspection targets in the antenna inspection system according to the present embodiment as an example of antenna means in the claims. Although the receiving antennas 1a to 1h may be used for any purpose, in this embodiment, in normal use, a capsule endoscope (subject introduction) introduced into the subject as will be described later. Used to receive radio signals transmitted from the device. In addition, as a specific structure of the receiving antennas 1a to 1h, for example, a loop antenna whose outer periphery is formed in a circular shape, and wiring that is electrically connected to the loop antenna and is connected to a receiving device or the like when used And a fixing mechanism for fixing the receiving antennas 1a to 1h on the body surface of the subject during normal use. In the example of FIG. 1, the number of receiving antennas 1 to be inspected is eight, but it is not necessary to interpret the number in a particularly limited manner.

  The antenna accommodating device 2 is for accommodating the receiving antennas 1a to 1h, and is for transmitting a radio signal for performance inspection to the receiving antennas 1a to 1h when accommodated. Specifically, as shown in FIG. 1, the antenna accommodating device 2 includes at least the accommodating portions 4 a to 4 h for accommodating the receiving antennas 1 a to 1 h and the receiving antennas 1 a to 1 h, respectively. Inspection signal transmission units 5a to 5h for transmitting inspection radio signals are provided.

  The accommodating portions 4a to 4h are provided in a number corresponding to the receiving antennas 1a to 1h to be inspected, and have shapes corresponding to the shapes of the receiving antennas 1a to 1h. In the present embodiment, the receiving antennas 1a to 1h have a loop antenna portion having a circular outer peripheral shape and a wiring portion extending from the loop antenna portion. Therefore, the accommodating portions 4a to 4h are also shown in FIG. As shown, the bottom surface is formed in a circular shape corresponding to the loop antenna portion, and a groove portion corresponding to the wiring portion.

  FIG. 2 is a block diagram illustrating an example of the inspection signal transmission unit 5a with respect to the configuration of the inspection signal transmission units 5a to 5h. As shown in FIG. 2, the inspection signal transmission unit 5 a is generated by an inspection signal generation unit 9 that generates an inspection signal based on the control of an inspection control unit 15 (described later) provided in the inspection apparatus 3, and the inspection signal generation unit 9. The transmission unit 10 that performs necessary processing such as modulation processing on the inspection signal that has been processed, and the transmission antenna 11 that transmits a radio signal that has been subjected to predetermined processing by the transmission unit 10 are provided. The transmitting antenna 11 is arranged in the vicinity of the accommodating portion 4a, and is configured to transmit a radio signal for inspection only to the receiving antenna 1a accommodated mainly in the corresponding accommodating portion 4a.

  The inspection signal generated by the inspection signal generation unit 9 may be any signal as long as it has a specific pattern that can be distinguished from noise. In this embodiment, the reception antenna is used during normal use. An inspection signal having a signal pattern similar to the pattern of the radio signal received by 1a to 1h is generated. Specifically, in the present embodiment, as will be described later, since the radio signals received by the receiving antennas 1a to 1h include the image signal, the inspection signal generation unit 9 has the same signal pattern as the image signal. It is preferable to generate an inspection signal having Furthermore, it is preferable to use a radio signal for inspection that includes data related to an image similar to an image transmitted during normal use. Specifically, as will be described later, since the receiving antennas 1a to 1h are used in the in-subject information acquisition system, for example, data related to an image similar to the in-subject image captured by the in-subject introduction apparatus. It is good also as producing | generating the radio signal for a test | inspection using.

  Next, the inspection apparatus 3 will be described. The inspection device 3 not only has a function of processing radio signals for inspection received via the reception antennas 1a to 1h when the reception antennas 1a to 1h are accommodated in the antenna accommodation device 2. The receiving antennas 1a to 1h have a function as a receiving apparatus that performs predetermined processing on radio signals received during normal use. As shown also in FIG. 1, the inspection device 3 includes a connection portion 6 for electrically connecting to the reception antennas 1 a to 1 h during inspection of the reception antennas 1 a to 1 h and during normal use, and at the time of performance inspection. And a display unit 7 that performs a display operation corresponding to the content of the radio signal received through each of the receiving antennas 1a to 1h, and the receiving antennas 1a to 1h are based on the display content of the display unit 7 at the time of performance inspection. Thus, it is possible for the inspector to perform a performance determination such as whether or not a disconnection has occurred.

  A specific configuration of the inspection apparatus 3 will be described. FIG. 3 is a block diagram showing the configuration of the inspection apparatus 3. As shown in FIG. 3, the inspection apparatus 3 includes a connection unit 6 for electrically connecting to the receiving antennas 1a to 1h, an antenna selecting unit 12 for selecting any of the receiving antennas 1a to 1h, and an antenna. An RF receiving unit 13 that performs demodulation processing or the like on a radio signal received via the receiving antenna 1 selected by the selection unit 12, and predetermined signal processing on the signal output from the RF receiving unit 13 And a signal processing unit 14 for performing. In addition, the inspection device 3 starts driving the inspection control unit 15 and the inspection control unit 15 that control the operation of the inspection signal generation unit 9 included in the antenna selection unit 12, the signal processing unit 14, and the antenna accommodating device 2 during the performance inspection. And a mode changeover switch 16 to be operated. Further, the inspection apparatus 3 includes a storage unit 17 for storing the signal output from the signal processing unit 14.

  The antenna selection unit 12 is for selecting any of the reception antennas 1 a to 1 h and outputting a radio signal received via the selected reception antenna 1 to the RF reception unit 13. Although any antenna selection algorithm by the antenna selection unit 12 may be used, in this embodiment, the antenna selection unit 12 is configured to select the reception antenna 1 having the strongest reception strength. .

  The signal processing unit 14 is for performing predetermined processing on the signal input from the RF receiving unit 13. In addition, the signal processing unit 14 has a function of switching the output destination of the processed signal according to the operation mode of the inspection device 3. Specifically, the signal processing unit 14 outputs the processed signal to the display unit 7 during the performance inspection. In normal use, it has a function of outputting to the storage unit.

  The inspection control unit 15 is for controlling the operations of the inspection device 3 and the antenna accommodating device 2 during the performance inspection of the receiving antennas 1a to 1h. Specifically, the inspection control unit 15 has a configuration in which an operation is started by switching the mode change switch 16, and the signal processing unit 14 provided in the inspection device 3 and the inspection signal generation unit provided in the antenna accommodation device 2 during operation. 9 has a function of controlling. A specific control operation by the inspection control unit 15 will be described in detail later.

  The storage unit 17 is for storing predetermined information generated based on radio signals transmitted from the in-subject introduction apparatus and received via the receiving antennas 1a to 1h, for example, in-subject images. is there. Specifically, the storage unit 17 has a function as a recording unit that outputs and records data to, for example, a portable recording medium 29 described later, which is one of recording media.

  In addition to the above-described constituent elements, the inspection apparatus 3 includes constituent elements for generating a radio signal to be transmitted to the in-subject introduction apparatus during normal use. Specifically, the inspection apparatus 3 controls the input of the oscillator 18 that defines the oscillation frequency of the wireless signal that is generated and transmitted, and the control information for controlling the drive of the in-subject introduction apparatus. A control information input unit 21 that generates an information signal, a superposition circuit 19 that superimposes a power feeding signal and a control signal, and an amplifier circuit 20 that amplifies the superposed signal are provided. The signal amplified by the amplifier circuit 20 is sent to the power feeding antennas 22a to 22n, and transmitted to the in-subject introduction apparatus via the power feeding antennas 22a to 22n.

  Further, the inspection device 3 includes a power supply unit 23 for driving the above-described components. The power supply unit may have a configuration in which a storage battery or the like is incorporated and distributed to each component, or only a configuration that distributes power supplied from an external storage battery or the like to each component. Also good.

  Next, the operation of the antenna inspection system according to this embodiment will be described. FIG. 4 is a flowchart for explaining the operation of the inspection control unit 15 during the performance inspection of the receiving antennas 1a to 1h in the antenna inspection system according to the present embodiment. Hereinafter, the operation of the antenna inspection system according to the present embodiment will be described focusing on the operation of the inspection control unit 15 with reference to FIG. 4 as appropriate.

  First, the inspection control unit 15 instructs the signal processing unit 14 to switch the output destination of the processed signal to the display unit 7 (step S101). By performing such an instruction, the reception content of the radio signal received via the receiving antennas 1 a to 1 h is displayed on the display unit 7.

  And the test | inspection control part 15 determines test object from the receiving antennas 1a-1h, and notifies the identification information of the receiving antenna 1 determined as test object to a predetermined component (step S102). Specifically, the inspection control unit 15 notifies the signal processing unit 14 of the identification information of the receiving antenna 1 determined as the inspection target. In response to this notification, the signal processing unit 14 outputs the identification information of the receiving antenna 1 determined as the inspection target to the display unit 7 together with the signal subjected to the predetermined processing in the subsequent step. .

  Thereafter, the inspection control unit 15 selects the inspection signal transmission unit 5 corresponding to the receiving antenna 1 determined as the inspection target from the inspection signal transmission units 5a to 5h provided in the antenna accommodation apparatus 2, and selects the selected inspection signal. The test signal generation unit 9 provided in the transmission unit 5 is instructed to generate a test signal (step S103). Specifically, for example, when the reception antenna 1a is determined as an inspection target, the inspection signal generation unit 9 provided in the inspection signal transmission unit 5a disposed in the vicinity of the accommodation unit 4a that accommodates the reception antenna 1a is used. To instruct the generation of the inspection signal. The corresponding inspection signal generation unit 9 receives the instruction, generates an inspection signal, outputs the generated inspection signal to the transmission unit 10, and the transmission unit 10 performs a modulation process or the like on the inspection signal and transmits the transmission antenna. A wireless signal for inspection is transmitted through the terminal 11.

  The transmitted radio signal is received via the receiving antenna 1 to be inspected determined in step S102, and is sequentially input to the antenna selection unit 12 and the RF receiving unit 13 via the connection unit 6. After undergoing demodulation processing or the like in the RF receiving unit 13, the signal processing unit 14 performs predetermined signal processing on the input signal and displays the processed signal with identification information of the inspection target. Output to unit 7. And the display part 7 displays the content of the radio signal received via the receiving antenna 1 to be inspected and the identification information of the inspection object, and the inspector confirms the display content of the display part 7, The quality of the receiving antenna 1 to be inspected is judged as good or bad, for example, whether there is a disconnection.

  Thereafter, the inspection control unit 15 determines whether or not the inspection has been completed for all the receiving antennas 1 (step S104). If it is determined in this step that the performance inspection has not been completed for all of the receiving antennas 1a to 1h, the process returns to step S102 again, and the receiving antenna 1 that has not been inspected is determined as the inspection target. Repeat the process.

  On the other hand, if it is determined in step S104 that the performance inspection has been completed for all of the receiving antennas 1a to 1h, the inspection control unit 15 outputs the processed signal to the signal processing unit 14. An instruction is given to switch the destination to the storage unit 17 (step S105). The inspection device 3 functions as a receiving device as will be described later when the receiving antennas 1a to 1h are normally used, and outputs a processed signal to the portable recording medium via the storage unit 17 when functioning as the receiving device. This is necessary. With the above, the operation of the inspection control unit 15 ends, and the performance inspection for the receiving antennas 1a to 1h by the antenna inspection system according to the present embodiment also ends.

  Next, an in-vivo information acquiring system configured using the inspection apparatus 3 that is a component of the antenna inspection system according to the present embodiment and the receiving antennas 1a to 1h that are inspection targets will be briefly described. . As already described, the receiving antennas 1a to 1h have a function of receiving a radio signal transmitted from the intra-subject introduction device during normal use, and the inspection device 3 is configured to receive the normal signals of the receiving antennas 1a to 1h. In use, it has a function of performing predetermined processing on radio signals received via the receiving antennas 1a to 1h, and it is possible to configure an in-vivo information acquisition system using these.

  FIG. 5 is a schematic diagram illustrating a configuration of an in-vivo information acquisition system using the inspection apparatus 3 and the like. As shown in FIG. 5, in the in-subject information acquisition system using the receiving antennas 1 a to 1 h and the inspection device 3, the inspection device 3 is used in a state attached to the subject 26 and connected to the inspection device 3. The receiving antennas 1a to 1h are used in a state where the receiving antennas 1a to 1h are pasted on the body surface of the subject 26 with a predetermined distance therebetween. Although not shown in FIG. 5, the power supply antennas 22 a to 22 n are also used in a state where they are attached to the body surface of the subject 26, similarly to the reception antennas 1 a to 1 h. In addition, in addition to these components, the intra-subject information acquisition system captures an image using a capsule endoscope 27 that is an example of an intra-subject introduction apparatus that is introduced into the subject 26, and the capsule endoscope 27. A display device 28 for displaying an image in the subject 26 and a portable recording medium 29 for transferring information between the inspection device 3 and the display device 28.

  The capsule endoscope 27 functions as an in-subject introduction apparatus that is introduced into the subject 26. The capsule endoscope 27 includes, for example, a predetermined function execution unit such as an imaging device that images the inside of the subject 26, and also includes a wireless transmission unit that transmits information regarding the subject 26 acquired by the predetermined function execution unit to the outside. Have a configuration. In the first embodiment, as described above, the inspection apparatus 3 generates a radio signal including a power feeding signal and wirelessly transmits the power signal via the power feeding antennas 22a to 22n. A receiving mechanism that receives a signal, a power mechanism that regenerates the received power supply signal as power, and a power storage mechanism that stores the regenerated power.

  The display device 28 is for displaying an image or the like in the subject 26 acquired by the capsule endoscope 27, and performs image display based on data supplied via the portable recording medium 29. It has a configuration such as a workstation. Specifically, the display device 28 may be configured to directly display an image by a CRT display, a liquid crystal display, or the like, or may be configured to output an image to another medium such as a printer.

  The portable recording medium 29 is detachable from the inspection device 3 and the display device 28, and has a structure capable of outputting and recording information when attached to both. Specifically, the portable recording medium 29 is attached to the inspection apparatus 3 while the capsule endoscope 27 is moving in the body cavity of the subject 26, and displays information regarding the position of the capsule endoscope 27. Record. Specifically, it is attached to the storage unit 17 provided in the inspection apparatus 3 and information is acquired via the storage unit 17. The portable recording medium 29 is configured such that after the capsule endoscope 27 is ejected from the subject 26, the portable recording medium 29 is taken out from the inspection apparatus 3 and attached to the display device 28, and the recorded data is read by the display device 28. Have. When data is transferred between the inspection device 3 and the display device 28 using a portable recording medium 29 such as a compact flash (registered trademark) memory, the inspection device 3 and the display device 28 are connected by wire. Unlike the capsule endoscope 27, the subject 26 can freely move even when the capsule endoscope 27 is moving inside the subject 26.

  The operation of the in-vivo information acquiring system shown in FIG. 5 will be briefly described. As shown in FIG. 5, the capsule endoscope 27, which is one aspect of the in-subject introduction apparatus, is introduced into the subject 26 through the mouth of the subject 26. Since the capsule endoscope 27 is introduced into the subject 26 and sequentially moves from the oral cavity to the esophagus, stomach, small intestine, and large intestine, each part in the subject 26 is moved along with the movement. In addition to acquiring the image data, a wireless signal is generated based on the acquired image data, and the generated wireless signal is transmitted to the outside of the subject 26.

  The transmitted radio signal is received via any of the receiving antennas 1 a to 1 h connected to the inspection device 3. In the inspection device 3, the antenna selection unit 12 selects the reception antenna 1 a to 1 h having the highest reception intensity of the radio signal transmitted from the capsule endoscope 27, and the selected reception antenna 1 is selected. The wireless signal is sequentially output to the RF receiving unit 13 and the signal processing unit 14 via the. Since the signal processing unit 14 switches the output destination to the storage unit 17 under the control of the inspection control unit 15 as shown in step S105 of FIG. 4, the predetermined processing by the signal processing unit 14 is performed. The finished signal is recorded on the portable recording medium 29 via the storage unit 17.

  The above-described operation by the inspection apparatus 3 is repeated until the capsule endoscope 27 is discharged out of the subject 26. After the capsule endoscope 27 is ejected to the outside of the subject 26, the portable recording medium 29 is detached from the inspection apparatus 3 and attached to the display apparatus 28. As a result of the inspection apparatus 3 repeatedly performing the above operation, the portable recording medium 29 stores image data of the region through which the capsule endoscope 27 has passed. Accordingly, the display device 28 visually displays the in-vivo image of the subject 26 by reading the image data recorded on the portable recording medium 29. This completes the operation of the in-vivo information acquisition system.

  Next, advantages of the antenna inspection system according to the present embodiment will be described. First, the antenna inspection system according to the present embodiment has a configuration in which the antenna accommodation apparatus 2 includes not only the accommodation unit 4 but also the inspection signal transmission unit 5. For this reason, the antenna accommodating device 2 not only has a function of accommodating the receiving antennas 1a to 1h when not in use, but also can perform a performance test in a state in which the receiving antennas 1a to 1h are accommodated. Have advantages.

  As described above, in the conventional inspection method for the receiving antenna used in the in-vivo information acquisition system, the receiving antenna is appropriately brought close to the inspection signal transmitting apparatus that transmits the inspection radio signal. Therefore, when performing a performance inspection using such a method, there is a problem that the burden on the inspector increases.

  On the other hand, the antenna inspection system according to the present embodiment employs a configuration in which inspection signal transmission units 5a to 5h are provided in a housing device that houses a receiving antenna when not in use. Therefore, it is possible to perform a performance test without bothering the examiner by appropriately controlling the operation of the test signal transmitting units 5a to 5h in a state where the receiving antennas 1a to 1h are accommodated in the accommodating units 4a to 4h. It has the advantage of being.

  In addition, accommodating the receiving antennas 1a to 1h in the accommodating portions 4a to 4h means that the use of the receiving antennas 1a to 1h is finished. When the antenna inspection system according to the present embodiment includes the inspection signal transmission units 5a to 5h inside the antenna accommodating device 2, the receiving antennas 1a to 1h are accommodated in the antenna accommodating device 2. It is possible to perform a performance test. As a result, there is an advantage that the performance test can be performed without interfering with the functions of the receiving antennas 1a to 1h during normal use.

  Moreover, in this Embodiment, while providing the some accommodating part 4a-4h corresponding to the receiving antennas 1a-1h in the antenna accommodating apparatus 2, the test signal corresponding to each vicinity of the accommodating part 4a-4h is provided. The transmitters 5a to 5h are provided. The antenna inspection system according to the present embodiment employs a configuration in which the inspection signal transmission units 5a to 5h are sequentially driven by the inspection control unit 15 provided in the inspection apparatus 3, and therefore a plurality of receiving antennas 1 are simultaneously used. For this reason, it is possible to prevent a wireless signal for inspection from being transmitted.

  As already described, in general, when receiving a radio signal via a plurality of receiving antennas, the receiving device (inspection device in the present embodiment) selects the receiving antenna having the strongest receiving strength and receives the receiving antenna. In this configuration, the wireless signal received via the wireless communication device performs predetermined processing. However, when a radio signal for inspection is simultaneously transmitted to a plurality of receiving antennas in a system that allows a receiving apparatus having such a configuration to function as an inspection apparatus, the receiving antenna in which a disconnection or the like has occurred is not always selected. However, there is a problem that a receiving antenna having a problem cannot be detected. For this reason, conventionally, it is necessary to devise measures such as selecting reception antennas one by one and bringing them closer to the inspection signal transmission device, and the performance inspection is complicated in this respect.

  In contrast, in the inspection system according to the present embodiment, inspection signal transmission units 5a to 5h that operate independently are arranged in the vicinity of the reception antennas 1a to 1h accommodated in the accommodation units 4a to 4h. It has a configuration. Therefore, for example, when performing a performance test of the receiving antenna 1a, if a test radio signal is transmitted only from the test signal transmitting unit 5a arranged in the vicinity, the receiving antennas 1b to 1h are used for testing. Is not received, and any of the receiving antennas 1b to 1h is not selected by the antenna selection unit 12 provided in the inspection apparatus 3. For this reason, in the inspection system according to the present embodiment, it is possible to avoid the occurrence of a problem that the receiving antenna 1 to be inspected is not selected in the inspection device 3 without any special contrivance by the inspector. It has the advantage of being.

(Modification 1)
Next, a first modification of the antenna inspection system according to the present embodiment will be described. The antenna inspection system according to the first modification has a configuration in which the housing unit includes an antenna housing device having a function of fixing the receiving antennas 1a to 1h at predetermined positions when the receiving antennas 1a to 1h are housed. . Note that components and the like not particularly mentioned below have the same configuration as that of the embodiment and exhibit the same functions. This also applies to Modification 2 and Modification 3 described later.

  FIG. 6 is a schematic diagram illustrating, as an example, the vicinity of the inspection signal transmission unit 5a in the configuration of the antenna accommodating device 31 provided in the antenna inspection system according to the first modification. As shown in FIG. 6, the antenna accommodating device 31 in the first modification includes a fixing member 33 for fixing the receiving antenna 1a at a predetermined position, and a rotating shaft 34 for operating the fixing member 33 to be rotatable. It has the accommodating part 32 provided with these.

  The fixing member 33 is fixed to the base material of the antenna housing device 31 so as to be rotatable about the rotating shaft 34. For example, the receiving member 33 receives a resilient force of a spring member (not shown) and receives the receiving antenna. It has a function of fixing the receiving antenna 1a at a predetermined position by applying a pressing force to 1a. Although not shown in the drawings, a concave portion matching the shape of the receiving antenna 1a is formed on the surface of the fixing member 33 or on the surface of the base material of the antenna accommodating device 31, and the pressing force by the fixing member 33 is applied. It is good also as a structure which accommodates the receiving antenna 1a in a recessed part. FIG. 6 shows only the vicinity of the inspection signal transmission unit 5a in the configuration of the antenna accommodating device 31, but the antenna accommodating device 31 in the first modification corresponds to each of the receiving antennas 1b to 1h. Of course, a similar accommodating part is also arranged in the vicinity of the inspection signal transmitting parts 5b to 5h.

  Advantages of the antenna inspection system according to the first modification will be described. As described above, in the first modification, the accommodating portion 32 has a configuration including the fixing member 33 that fixes each of the receiving antennas 1a to 1h at predetermined positions. Accordingly, the receiving antennas 1a to 1h are each fixed at a predetermined position while being accommodated in the antenna accommodating device 31, and are connected to the corresponding inspection signal transmitting units 5a to 5h when performing the performance inspection. The positional relationship will be fixed. Therefore, the antenna inspection system according to the first modification can always perform the performance inspection of the receiving antennas 1a to 1h under substantially the same conditions, and the inspector can check the performance of the receiving antennas 1a to 1h. It has the advantage that the quality can be judged uniformly.

(Modification 2)
Next, a second modification of the antenna inspection system according to the embodiment will be described. The antenna inspection system according to the second modification has a configuration in which an accommodation sensor unit that detects whether or not the reception antennas 1a to 1h are accommodated is provided in the antenna accommodation device.

  FIG. 7 is a schematic diagram illustrating, by way of example, the vicinity of the accommodating portion 4a and the inspection signal transmitting portion 5a with respect to the configuration of the antenna accommodating device that forms the antenna inspection system according to the second modification. As shown in FIG. 7, the antenna accommodation device 36 includes an accommodation sensor portion 37 in the vicinity of the accommodation portion 4a. In addition, although illustration was abbreviate | omitted, it cannot be overemphasized that it has the structure similar to the structure shown in FIG. 7 also about the part corresponding to the accommodating parts 4b-4h and the test | inspection signal transmission parts 5b-5h.

  The accommodation sensor unit 37 is for determining whether or not the receiving antenna 1a is accommodated in the accommodation unit 4a. Specifically, the accommodation sensor unit 37 is disposed, for example, in a state of being exposed on the bottom surface of the accommodation unit 4a, and the reception unit 1a has a mechanism for detecting the presence or absence of contact with the reception antenna 1a. It is determined whether 1a is accommodated. The accommodation sensor unit 37 is configured to output a determination result to the inspection control unit 15 provided in the inspection device 38.

  Corresponding to the fact that the antenna accommodation device 36 includes the accommodation sensor unit 37, the driving state of the inspection device 38 is controlled based on the determination result output from the accommodation sensor unit 37. Therefore, the inspection device 38 in this modification has a configuration in which the mode change switch 16 is omitted, and operates in the performance inspection mode based on the determination result of the accommodation sensor unit 37. In FIG. 7, the components other than the inspection control unit 15 are omitted from the inspection device 38, but the mode change switch 16 is omitted from the inspection device 38, and the inspection control unit 15 is connected to the housing sensor unit 37. Except for being connected, it has the same configuration as the inspection apparatus 3 shown in FIG.

  Next, advantages of the antenna inspection system according to the second modification will be described. In the second modification, the accommodation sensor unit 37 has a function of determining whether or not the receiving antennas 1 a to 1 h are accommodated in the antenna accommodation device 36, and the inspection control unit 15 uses the determination result by the accommodation sensor unit 37. It has the structure which drives based. Therefore, in the antenna inspection system according to the second modification, as soon as the receiving antennas 1a to 1h are accommodated in the antenna accommodating device 36, it is possible to quickly start the performance inspection of the receiving antennas 1a to 1h.

  In addition, by appropriately adjusting the detection sensitivity, the accommodation sensor unit 37 can determine whether or not the reception antennas 1a to 1h are appropriately accommodated in the accommodation units 4a to 4h. Therefore, in the case of such a configuration, when the accommodation units 4a to 4h are not properly accommodated and the positional relationship between the inspection signal transmission units 5a to 5h and the reception antennas 1a to 1h is shifted, It is possible to prevent the start of the performance inspection, and to perform the performance inspection only when the inspection signal transmission units 5a to 5h and the receiving antennas 1a to 1h have a predetermined positional relationship.

(Modification 3)
Next, Modification 3 of the antenna inspection system according to the embodiment will be described. The antenna inspection system according to the third modification has a configuration that newly includes a display device that visually displays the contents of radio signals received via the receiving antennas 1a to 1h during the performance inspection.

  FIG. 8 is a schematic diagram showing a configuration of an inspection device 39 provided in the antenna inspection system according to the third modification and a display device 41 that visually displays the contents of a radio signal received during the performance inspection. As shown in FIG. 8, the inspection device 39 includes an output unit 40 for outputting a signal processed by the signal processing unit 14 to the outside instead of the display unit 7 provided in the inspection device 3 shown in FIG. The display device 41 includes an input unit 42 for inputting a signal output via the output unit 40, a signal processing unit 43 for performing predetermined processing on the input signal as necessary, and signal processing And an image display unit 44 for visually displaying a signal processed by the unit 43 as necessary.

  The image display unit 44 has a configuration including a liquid crystal display, for example, and has a function of visually displaying an input signal. The image display unit 44 does not need to be interpreted as being limited to the one that directly displays visual information such as a liquid crystal display, and outputs the visual information to another medium such as a printer. It's also good.

  As described in the embodiment, at the time of performance inspection of the receiving antennas 1a to 1h, the signal processing unit 14 is predetermined with respect to the inspection radio signal received via any of the receiving antennas 1a to 1h. And a function of outputting the processed signal. Therefore, the image display unit 44 provided in the display device 41 visually displays the contents of the inspection radio signals received via the receiving antennas 1a to 1h. The image display unit 44 includes the receiving antenna. It has a function of displaying visual information corresponding to the reception status of radio signals received via 1a to 1h.

  The advantages of the antenna inspection system according to the third modification will be described. The antenna inspection system according to the third modification visually displays the contents of the wireless signal for inspection received via the receiving antennas 1a to 1h during the performance inspection by the image display unit 44 provided in the display device 41. It has a function. Therefore, the inspector can visually grasp the performance of the receiving antennas 1a to 1h, and determines whether each of the receiving antennas 1a to 1h has a performance suitable for normal use. It can be done easily.

  In particular, the antenna inspection system according to the third modification is effective when an image signal is included in the wireless signal for inspection. For example, when a radio signal including an in-subject image is used as an image signal as an examination radio signal, the in-subject image corresponding to the reception status is displayed on the image display unit 44 at the time of performance inspection. It will be. Here, when the examiner is a doctor or the like, it is possible to easily determine whether or not the displayed in-subject image can withstand the diagnosis, and a practical performance test is easily performed. Has the advantage that it is possible.

  In the third modification, there is an advantage that the display device 41 is provided separately from the inspection device 39. That is, as shown in FIG. 5, the inspection device 39 is used as a receiving device carried by the subject when the receiving antennas 1a to 1h are normally used. Therefore, increasing the size of the inspection device 39 is not preferable because it increases the burden on the subject during normal use. On the other hand, in the antenna inspection system according to the third modification, the display device 41 is configured to be provided independently and used only for performance inspection, so that reception via the receiving antennas 1a to 1h is performed. While enjoying the advantage that the contents can be visually grasped, it is possible to avoid an increase in the burden on the subject during normal use.

It is a mimetic diagram showing the whole antenna inspection system composition concerning an embodiment. It is a schematic diagram which shows a part of structure of the antenna accommodating apparatus which forms the antenna test | inspection system concerning embodiment. It is a block diagram which shows the structure of the test | inspection apparatus which forms the antenna test | inspection system concerning embodiment. It is a flowchart for demonstrating operation | movement of the test | inspection control part with which a test | inspection apparatus is equipped. It is a schematic diagram which shows the whole structure of the in-vivo information acquisition system comprised using the receiving antenna and test | inspection apparatus which are test objects. It is a schematic diagram which shows a part of structure of the antenna accommodating apparatus in the modification 1 of embodiment. It is a schematic diagram which shows a part of structure of the antenna accommodating apparatus in the modification 2 of embodiment. It is a block diagram which shows the structure of the test | inspection apparatus and display apparatus in the modification 3 of embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1a-1h Reception antenna 2 Antenna accommodation apparatus 3 Inspection apparatus 4a-4h Accommodation part 5a-5h Inspection signal transmission part 6 Connection part 7 Display part 9 Inspection signal generation part 10 Transmission unit 11 Transmission antenna 12 Antenna selection unit 13 RF reception unit DESCRIPTION OF SYMBOLS 14 Signal processing unit 15 Test | inspection control part 16 Mode change switch 17 Memory | storage unit 18 Oscillator 19 Superimposition circuit 20 Amplification circuit 21 Control information input unit 22a-22n Feeding antenna 23 Power supply unit 26 Subject 27 Capsule type endoscope 28 Display apparatus DESCRIPTION OF SYMBOLS 29 Portable recording medium 31 Antenna accommodating apparatus 32 Accommodating part 33 Fixing member 34 Rotating shaft 36 Antenna accommodating apparatus 37 Accommodating sensor part 38 Inspection apparatus 39 Inspection apparatus 40 Output part 41 Display apparatus 42 Input part 43 Signal processing part 44 Image table Part

Claims (9)

An antenna housing apparatus for housing antenna means formed so as to be able to receive a radio signal,
Accommodating means for accommodating the antenna means;
An inspection signal transmitting means that is disposed in the vicinity of the accommodating means and transmits a radio signal for inspection to the antenna means accommodated in the accommodating means;
An antenna accommodating device comprising: There are a plurality of the antenna means to be accommodated,
A plurality of the accommodating means are arranged corresponding to the number of the antenna means,
A plurality of the inspection signal transmission means are arranged according to the plurality of accommodation means,
The antenna accommodation apparatus according to claim 1, further comprising a control unit that sequentially selects and drives the plurality of inspection signal transmission units.   3. The antenna accommodation apparatus according to claim 1, wherein the accommodation unit includes a fixing unit that fixes a positional relationship between the antenna unit and the inspection signal transmission unit. The antenna means has a function of receiving a radio signal transmitted from an in-subject introduction apparatus that is introduced into a subject during normal use and has a radio transmission function,
The antenna accommodation apparatus according to claim 1, wherein the radio signal for examination includes a signal pattern similar to a radio signal transmitted from the intra-subject introduction apparatus. The antenna unit has an imaging function and a wireless transmission function, and has a function of receiving a wireless signal including captured image data that is introduced into the subject during normal use and transmitted from the in-subject introduction device. Have
The antenna accommodation apparatus according to claim 4, wherein the radio signal for examination includes image data similar to image data transmitted from the intra-subject introduction apparatus. An antenna inspection system comprising: an antenna accommodating device that accommodates a plurality of antenna means each configured to receive radio signals; and an inspection device that performs a performance inspection of the antenna means accommodated in the antenna accommodating device,
The antenna accommodating device is:
Accommodating means for accommodating the antenna means;
An inspection signal transmitting means arranged in the vicinity of the accommodating means and outputting a radio signal for inspection to the antenna means accommodated in the accommodating means;
With
The inspection device includes:
Connection means for electrically connecting to the antenna means;
Signal processing means for performing predetermined processing on the inspection signal received via the antenna means and input via the connection means;
An antenna inspection system comprising: The inspection device functions as a receiving device during normal use of the antenna means,
7. The antenna inspection system according to claim 6, wherein the signal processing means performs predetermined processing on a radio signal received via the antenna means.   The antenna inspection system according to claim 6 or 7, wherein the inspection apparatus further includes display means for displaying the contents of the signal processed by the signal processing means.   The antenna inspection system according to claim 6 or 7, further comprising a display device for visually displaying image data based on the signal processed by the signal processing means.

Images