JP2010016456A - Portable rfid reader-writer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To secure an appropriate communication performance in RFID communication and wireless LAN communication with each other. <P>SOLUTION: A first RFID antenna 8a is disposed along a Y axis direction, a second RFID antenna 8b is disposed along a Z axis direction, a first wireless LAN antenna 9a is disposed along the Y axis direction, and a second wireless LAN antenna 9b is disposed along an X axis direction. A polarization plane formed by the first RFID antenna 8a and a polarization plane formed by the second wireless LAN antenna 9b can be orthogonal, and a polarization plane formed by the second RFID antenna 8b and a polarization plane formed by one of the first wireless LAN antenna 9a and the second wireless LAN antenna 9b can be orthogonal. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a portable RFID reader / writer in which a casing is provided with RFID communication means for performing RFID communication with an RFID tag and wireless LAN communication means for performing wireless LAN communication with a wireless device. .

Conventionally, an RFID communication module that performs RFID communication with an RFID tag and a wireless LAN communication module that performs wireless LAN communication with an external wireless device are provided, and the data read from the RFID tag by the RFID communication module is wirelessly provided. There is provided a portable RFID reader / writer that transfers data from a LAN communication module to an external wireless device or writes data transferred from an external wireless device to a wireless LAN communication module from an RFID communication module to an RFID tag. In this type of portable RFID reader / writer, the RFID antenna connected to the RFID communication module is an antenna having linear polarization characteristics, and the wireless LAN antenna connected to the wireless LAN communication module is linear polarization characteristics. In the case of an antenna having an antenna, there is a problem that depending on the arrangement relationship between the two, the planes of polarization of each other approach each other, thereby reducing the communication performance of each other. On the other hand, Patent Document 1 discloses a configuration in which a part of functional blocks related to RFID communication and a part of functional blocks related to Bluetooth (registered trademark) communication are shared.
JP 2003-69486 A

  However, in the one described in Patent Document 1 described above, communication is caused by the close proximity of the polarization plane of the RFID antenna having linear polarization characteristics and the polarization plane of the wireless LAN antenna having linear polarization characteristics. It has not yet solved the problem of reducing the performance.

  The present invention has been made in view of the circumstances described above, and an object of the present invention is to perform wireless LAN communication between an RFID communication unit that performs RFID communication with an RFID tag and an external wireless device on a housing. An object of the present invention is to provide a portable RFID reader / writer capable of ensuring appropriate communication performance without degrading each other's communication performance in a configuration provided with wireless LAN communication means to perform.

  According to the invention described in claim 1, wireless LAN communication between an RFID antenna having linear polarization characteristics connected to an RFID communication means for performing RFID communication with an RFID tag and an external wireless device The wireless LAN antennas having linear polarization characteristics connected to the wireless LAN communication means for performing the above are arranged so that the polarization planes formed by them are orthogonal to each other. As a result, it is possible to realize a configuration in which the polarization plane of the RFID antenna having linear polarization characteristics and the polarization plane of the wireless LAN antenna having linear polarization characteristics are not close to each other, thereby reducing the communication performance of each other. Therefore, appropriate communication performance can be ensured.

  According to the second aspect of the present invention, the casing is formed in an elongated shape, two antennas are provided as RFID antennas, and two antennas are provided as wireless LAN antennas. And an antenna disposed along a direction orthogonal to the horizontal plane parallel to the longitudinal direction of the housing and an antenna disposed along a direction orthogonal to the longitudinal direction of the housing. The two wireless LAN antennas are in a horizontal plane parallel to the horizontal plane of the casing and are parallel to the horizontal plane of the casing and the antenna arranged along the direction perpendicular to the longitudinal direction of the casing. In combination with an antenna arranged along a direction perpendicular to the horizontal plane, an antenna arranged along the longitudinal direction of the casing on a horizontal plane parallel to the horizontal plane of the casing The combination of the antenna and the antenna arranged along the direction perpendicular to the horizontal plane parallel to the horizontal plane portion of the casing, the horizontal plane parallel to the horizontal plane portion of the casing and arranged along the longitudinal direction of the casing The antenna is arranged in a horizontal plane parallel to the horizontal plane portion of the casing, and the antenna is arranged along a direction orthogonal to the longitudinal direction of the casing. Thus, in a configuration in which two antennas are provided as RFID antennas and two antennas are provided as wireless LAN antennas, the wireless LAN having the polarization plane of the RFID antenna having linear polarization characteristics and the linear polarization characteristics A configuration in which the polarization plane of the antenna does not approach can be realized.

  According to the invention described in claim 3, the casing is formed in an elongated shape, and one antenna is provided as an RFID antenna and one antenna is provided as a wireless LAN antenna. The wireless LAN antenna is disposed along a direction perpendicular to the horizontal plane of the casing, and is disposed along a direction perpendicular to the longitudinal direction of the casing. ing. Accordingly, in a configuration in which one antenna is provided as the RFID antenna and one antenna is provided as the wireless LAN antenna, the wireless LAN having the polarization plane of the RFID antenna having the linear polarization characteristic and the linear polarization characteristic is provided. A configuration in which the polarization plane of the antenna does not approach can be realized.

  According to the invention described in claim 4, the casing is formed in an elongated shape, and one antenna is provided as an RFID antenna and two antennas are provided as wireless LAN antennas. The two wireless LAN antennas are arranged in a horizontal plane parallel to the horizontal plane of the casing and perpendicular to the longitudinal direction of the casing. A combination of an antenna arranged along a direction orthogonal to an antenna arranged along a direction perpendicular to a horizontal plane parallel to the horizontal plane of the casing, and a casing in a horizontal plane parallel to the horizontal plane of the casing. A combination of an antenna arranged along the longitudinal direction of the body and an antenna arranged along a direction perpendicular to the horizontal plane parallel to the horizontal plane of the casing, parallel to the horizontal plane of the casing A combination of an antenna disposed along a longitudinal direction of a housing and a planar antenna parallel to a horizontal plane portion of the housing and disposed along a direction orthogonal to the longitudinal direction of the housing. It is comprised by either. Thus, in a configuration in which one antenna is provided as the RFID antenna and two antennas are provided as the wireless LAN antenna, the wireless LAN having the polarization plane of the RFID antenna having the linear polarization characteristic and the linear polarization characteristic is provided. A configuration in which the polarization plane of the antenna does not approach can be realized.

  According to the invention described in claim 5, the casing is formed in an elongated shape, two antennas are provided as RFID antennas, and one antenna is provided as a wireless LAN antenna. And an antenna disposed along a direction orthogonal to the horizontal plane parallel to the longitudinal direction of the housing and an antenna disposed along a direction orthogonal to the longitudinal direction of the housing. One wireless LAN antenna is arranged along a direction orthogonal to a horizontal plane parallel to the horizontal plane portion of the casing, or is in a horizontal plane parallel to the horizontal plane portion of the casing and the length of the casing. It arrange | positions along the direction orthogonal to a direction. Accordingly, in the configuration in which two antennas are provided as the RFID antenna and one antenna is provided as the wireless LAN antenna, the wireless LAN having the polarization plane of the RFID antenna having the linear polarization characteristic and the linear polarization characteristic is provided. A configuration in which the polarization plane of the antenna does not approach can be realized.

  According to the invention described in claim 6, the wireless LAN antenna switching means performs wireless LAN communication between the wireless LAN communication means and the external wireless device every time the RFID communication means performs RFID communication with the RFID tag. In the mode to be performed, each time the RFID communication means is in RFID communication with the RFID tag, the received electric field strength of each of the two wireless LAN antennas is measured, and one of the two wireless LAN antennas is measured. Based on the result, the operation antenna is switched alternatively. As a result, when RFID communication is being performed with the RFID tag, one of the two wireless LAN antennas having the higher received electric field strength can be alternatively switched as the operating antenna, and wireless LAN communication is performed. Communication performance can be ensured appropriately.

  According to the invention described in claim 7, the wireless LAN antenna switching means performs wireless LAN communication between the wireless LAN communication means and the external wireless device every time the RFID communication means performs RFID communication with the RFID tag. In the mode to perform, immediately after the RFID communication means ends the RFID communication with the RFID tag, the received electric field strength of each of the two wireless LAN antennas is measured, and one of the two wireless LAN antennas is Based on the measurement result, the operation antenna is switched alternatively. As a result, immediately after the end of RFID communication with the RFID tag, one of the two wireless LAN antennas having the higher received electric field strength can be selectively switched as the operating antenna. Communication performance can be ensured appropriately.

  According to the invention described in claim 8, the RFID antenna switching means performs wireless LAN communication with an external wireless device every time the RFID communication means performs RFID communication with the RFID tag. In the aspect, after the wireless LAN communication means selects one of the two wireless LAN antennas whose polarization planes are orthogonal to each other, the RFID tag response level of each of the two RFID antennas is measured. Then, one of the two RFID antennas is alternatively switched as an operating antenna based on the measurement result. As a result, after selecting one of the two wireless LAN antennas whose polarization planes are orthogonal to each other, the antenna with the higher response level of the two RFID antennas is selected as the operating antenna. The communication performance when performing RFID communication can be ensured appropriately.

  According to the ninth aspect of the present invention, the wireless LAN antenna switching means is configured such that after the RFID communication means performs RFID communication for a preset number of times with the RFID tag, the wireless LAN communication means is externally connected. In the aspect of performing wireless LAN communication with a device, immediately after the RFID communication means ends RFID communication for a set number of times with the RFID tag, the received electric field strength of each of the two wireless LAN antennas is measured, One of the two wireless LAN antennas is alternatively switched as an operating antenna based on the measurement result. As a result, immediately after the RFID communication for the set number of times with the RFID tag is completed, one of the two wireless LAN antennas having the higher received electric field strength can be selectively switched as the operating antenna. It is possible to appropriately ensure the communication performance when performing the above.

(First embodiment)
A first embodiment in which the present invention is applied to a portable RFID reader / writer having an information code reading function for optically reading data recorded in an information code (one-dimensional code or two-dimensional code) will be described below with reference to FIG. It will be described with reference to FIG. FIG. 1 schematically shows an arrangement mode of an RFID communication antenna and a wireless LAN communication antenna.

  The portable RFID reader / writer 1 has a casing 2 made of, for example, a plastic material, which is combined with an upper case 3 and a lower case 4 to form an elongated shape as a whole. The upper half of the casing is recorded in an information code. The optical reading unit 6 is provided with a reading port 5 having an opening surface parallel to the reading surface of an optical reading sensor (not shown) that optically reads the data being read, the lower half of which can be gripped by the user The grip 7 is used. The gripping part 7 is formed in a slightly narrower shape than the optical reading part 6. In the present embodiment, thereafter, the longitudinal direction of the housing 2 in the horizontal plane parallel to the horizontal surface portions of the housing 2 (the flat portion 3a of the upper case 3 and the flat portion 4a of the lower case 4) is the X-axis direction, A direction that is in a horizontal plane parallel to the horizontal plane of the housing 2 and that is orthogonal to the longitudinal direction of the housing 2 is defined as a Y-axis direction, and a direction that is orthogonal to a horizontal plane parallel to the horizontal plane of the housing 2 is described as a Z-axis direction.

  An RFID communication module 8 (RFID communication means, RFID antenna switching means in the present invention) that performs RFID communication with the RFID tag 20 (see FIG. 2) is disposed inside the housing 2 and accessed. A wireless LAN communication module 9 (wireless LAN communication means, wireless LAN antenna switching means in the present invention) that performs wireless LAN communication with the point 21 (external wireless device in the present invention) (see FIG. 2) is disposed. Yes.

  The RFID communication module 8 connects two antennas 8a and 8b, a first RFID antenna 8a and a second RFID antenna 8b. These two antennas 8a and 8b are composed of dipole antennas having linear polarization characteristics, and the first RFID antenna 8a has the element axis arranged along the Y-axis direction, and the second RFID In the antenna 8b, the axis of the element is arranged along the Z-axis direction. The RFID communication module 8 transmits the carrier wave modulated by the transmission data to the RFID tag 20 from either the first RFID antenna 8a or the second RFID antenna 8b, and the carrier wave transmitted from the RFID tag 20 is the first carrier wave. Data is transmitted to and received from the RFID tag 20 by extracting the received data by demodulating the received carrier wave with the received RFID antenna 8a or the second RFID antenna 8b. In this case, the frequency band used for RFID communication is, for example, the 953 [MHZ] band.

  The wireless LAN communication module 9 connects two antennas 9a and 9b, which are a first wireless LAN antenna 9a and a second wireless LAN antenna 9b. These two antennas 9a and 9b are composed of dipole antennas having linear polarization characteristics, and the first wireless LAN antenna 9a has the element axis arranged along the Y-axis direction, The wireless LAN antenna 9b has an element axis arranged along the X-axis direction. The wireless LAN communication module 9 transmits the carrier wave modulated by the transmission data to the access point 21 from either the first wireless LAN antenna 9a or the second wireless LAN antenna 9b, and the carrier wave transmitted from the access point 21 Is received by either the first wireless LAN antenna 9a or the second wireless LAN antenna 9b, and the received carrier wave is demodulated to extract the received data, thereby transmitting and receiving data to and from the access point 21. Do. In this case, the frequency band used in the wireless LAN communication is, for example, 2 [GHZ] band or 5 [GHZ] band.

  FIG. 2 is a functional block diagram showing the electrical configuration of the portable RFID reader / writer 1 described above. The portable RFID reader / writer 1 includes a control unit 10, the above-described RFID communication module 8, the above-described wireless LAN communication module 9, a display unit 11, a key input unit 12, an image recognition module 13, and a power supply unit 14. And is configured. The control unit 10 is configured mainly with a microcomputer, and controls the overall operation of the portable RFID reader / writer 1 by executing a control program.

  The display unit 11 includes a liquid crystal display (not shown) provided on the upper surface 3a of the upper case 3 in the housing 2, and when a display command signal is input from the control unit 10, the input display Various information is displayed based on the command signal. The key input unit 12 has a key top (not shown) provided on the upper surface portion 3a of the upper case 3 in the casing 2, and receives an operation detection signal indicating the operation content of the user operating the key top. Output to the control unit 10. When the image recognition module 13 inputs an image signal in response to optical reading of the data recorded in the information code by the off-shore optical reading sensor, the image recognition module 13 extracts an image from the input image signal, and extracts the extracted image signal. The recognized image is subjected to image recognition based on a predetermined image recognition algorithm to generate image recognition data, and the generated image recognition data is output to the control unit 10. The power supply unit 14 generates operating power from the power supplied from the battery 15 and supplies it to each functional block.

  The RFID communication module 8 is provided so as to be mounted on an expansion board inside the housing 2, and includes an RF unit 16, a reader / writer IC 17, an FPGA 18, and a CF card interface (I / F) 19. It is configured. The RFID communication module 8 (RF unit 16) is a selection circuit (not shown) that selectively selects (switches) one of the first RFID antenna 8a and the second RFID antenna 8b as an operating antenna. The antenna selection diversity is performed by alternatively selecting one of the first RFID antenna 8a and the second RFID antenna 8b as an operation antenna. The wireless LAN communication module 9 includes a selection circuit (not shown) that selectively selects (switches) one of the wireless LAN antenna 9a and the second wireless LAN antenna 9b as an operation antenna. Then, antenna selection diversity is performed by selectively selecting one of the first wireless LAN antenna 9a and the second wireless LAN antenna 9b as an operation antenna.

  The control unit 10 controls the RFID communication performed by the RFID communication module 8 with the RFID tag 20 and the wireless LAN communication performed by the wireless LAN communication module 9 with the access point 21, so that the RFID communication module 8 Data read from the RFID tag 20 is transferred from the wireless LAN communication module 9 to the access point 21, and data transferred from the access point 21 to the wireless LAN communication module 9 is written from the RFID communication module 8 to the RFID tag 20. .

  Next, the operation of the above configuration will be described with reference to FIGS. As a mode in which the portable RFID reader / writer 1 reads (takes in) data from the RFID tag 20 and transfers the read data to the access point 21, the read 1 is read every time the data is read from the RFID tag 20. Sequential read transfer for transferring the data for the number of times to the access point 21 and batch reading for transferring the data for the set number of times read to the access point 21 after reading the data from the RFID tag 20 for a preset number of times. There are two types of transfer. Hereinafter, these aspects will be sequentially described. Note that the user can alternatively set one of sequential reading transfer and batch reading transfer by operating the portable RFID reader / writer 1 in advance.

(1) Sequential Read Transfer When the portable RFID reader / writer 1 performs sequential read transfer, the RFID communication process in the RFID communication module 8 and the wireless LAN communication process in the wireless LAN communication module 9 are performed in parallel.

  The portable RFID reader / writer 1 monitors whether or not a data reading instruction is generated from the RFID tag 20 (step S1). Here, the portable RFID reader / writer 1 receives a data read instruction from the RFID tag 20 based on an operation detection signal from the key input unit 12 when the user performs an operation of a data read instruction from the RFID tag 20. If it is determined that it has occurred ("YES" in step S1), the process proceeds to RFID antenna selection control (step S2). In addition, the portable RFID reader / writer 1 is arranged in such a manner that the plane of polarization is orthogonal to both the first RFID antenna 8a and the second RFID antenna 8b in parallel with the shift to the RFID antenna selection control. The second wireless LAN antenna 9b is selected as an operating antenna (step S11), and the selected second wireless LAN antenna 9b is connected to the access point 21 (step S12).

  When the portable RFID reader / writer 1 shifts to the RFID antenna selection control, the portable RFID reader / writer 1 first selects the first RFID antenna 8a as an operating antenna (step S21), and the RFID tag response level at the selected first RFID antenna 8a. And the measured value (LV1) is stored (step S22). Subsequently, the portable RFID reader / writer 1 selects the second RFID antenna 8b as an operating antenna (step S23), measures the RFID tag response level at the selected second RFID antenna 8b, and measures the measured value ( LV2) is stored (step S24).

  Next, the portable RFID reader / writer 1 compares the measured value (LV1) of the RFID tag response level at the first RFID antenna 8a with the measured value (LV2) of the RFID tag response level at the second RFID antenna 8b. If it is determined that the former is greater than or equal to the latter ("YES" in step S25), the first RFID antenna 8a is selected as the operating antenna (step S26), while the former is not greater than or equal to the latter. If it is determined that (the former is less than the latter) (“NO” in step S25), the second RFID antenna 8b is selected as the operating antenna (step S27), the RFID antenna selection control is terminated, and the process returns. Then, the portable RFID reader / writer 1 starts RFID communication with the RFID tag 20 using the RFID antenna selected by the RFID antenna selection control (step S3).

  In addition, the portable RFID reader / writer 1 uses the RFID antenna selected by the RFID antenna selection control to start RFID communication with the RFID tag 20 and simultaneously performs the first RFID antenna 8a by the RFID antenna selection control. It is determined whether or not one of the second RFID antennas 8b has been selected (step S13), and if it is determined that the first RFID antenna 8a has been selected, the selected first RFID antenna 8a and the polarization plane are determined. Continues to select the second wireless LAN antenna 9b arranged in an orthogonal relationship as an operating antenna (step S14). On the other hand, if it is determined that the second RFID antenna 8b has been selected, the selected second wireless LAN antenna 9b is selected. The first wireless LAN antenna 9a is disposed in such a manner that the two RFID antennas 8b and the plane of polarization are orthogonal to each other. Beauty shifts to the wireless LAN antenna selection control for selecting one as the active antennas of the first wireless LAN antenna 9b (step S15).

  When shifting to wireless LAN antenna selection control, the portable RFID reader / writer 1 first selects the first wireless LAN antenna 9a as an operating antenna (step S31), and reception by the selected first wireless LAN antenna 9a. The electric field strength is measured, and the measured value (RSSI1) is stored (step S32). Subsequently, the portable RFID reader / writer 1 selects the second wireless LAN antenna 9b as an operating antenna (step S33), measures the received electric field strength at the selected second wireless LAN antenna 9b, and the measured value. (RSSI2) is stored (step S34).

  Next, the portable RFID reader / writer 1 compares the measured value (RSSI1) of the received electric field strength at the first wireless LAN antenna 9a with the measured value (RSSI2) of the received electric field strength at the second wireless LAN antenna 9b. If it is determined that the former is greater than or equal to the latter (“YES” in step S35), the first wireless LAN antenna 9a is selected as the operating antenna (step S36), while the former is greater than or equal to the latter. If it is determined that the former is less than the latter (“NO” in step S35), the second wireless LAN antenna 9b is selected as the operating antenna (step S37), and the wireless LAN antenna selection control is terminated. Return. Then, the portable RFID reader / writer 1 is connected to the access point 21 by the wireless LAN antenna selected from the first wireless LAN antenna 9a and the second wireless LAN antenna 9b (step S16).

  That is, when the portable RFID reader / writer 1 selects the first RFID antenna 8a by the RFID antenna selection control, the second wireless LAN antenna 9b is used as the operating antenna without performing the wireless LAN antenna selection control. Since the selection is continued, the second wireless LAN antenna 9b is connected to the access point 21. On the other hand, since the portable RFID reader / writer 1 performs the wireless LAN antenna selection control when the second RFID antenna 8b is selected by the RFID antenna selection control, the first wireless LAN antenna 9a and the second wireless LAN are controlled. The antenna 9b is connected to the access point 21 by the one having the higher received electric field strength.

  Next, after starting the RFID communication with the RFID tag using the RFID antenna selected by the RFID antenna selection control, the portable RFID reader / writer 1 monitors whether or not the RFID communication is terminated. If it is determined that the RFID communication has been terminated (“YES” in step S4), the wireless LAN antenna selection control is resumed (step S17), and the first wireless LAN antenna 9a and the second wireless LAN antenna 9a The wireless LAN antenna 9b of the wireless LAN antenna 9b is connected to the access point by the one having the higher received electric field strength (step S18), and the series of processes is terminated.

  Through the processing described above, in the portable RFID reader / writer 1, when performing sequential reading and transfer, the RFID communication processing and the wireless LAN communication processing are performed in parallel, so that wireless communication can be performed while RFID communication is being performed. By performing LAN antenna selection control, one of the first wireless LAN antenna 9a and the second wireless LAN antenna 9b having the higher received electric field strength is selected as the operating antenna, and immediately after the RFID communication is finished, the wireless LAN antenna By performing selection control, the higher one of the reception electric field strengths of the first wireless LAN antenna 9a and the second wireless LAN antenna 9b is selected as the operating antenna.

(2) Batch Reading / Transfer The portable RFID reader / writer 1 performs RFID communication processing in the RFID communication module 8 and wireless LAN communication processing in the wireless LAN communication module 9 in tandem when performing batch reading / transfer.

  The portable RFID reader / writer 1 monitors whether or not a data read instruction from the RFID tag 20 has been generated in a state where a set number of times for transferring the data read from the RFID tag 20 at a time is stored in advance. (Step S41). Here, the portable RFID reader / writer 1 receives a data read instruction from the RFID tag 20 based on an operation detection signal from the key input unit 12 when the user performs an operation of a data read instruction from the RFID tag 20. If it is determined that it has occurred (“YES” in step S41), the process proceeds to the RFID antenna selection control described above (step S42).

  Next, the portable RFID reader / writer 1 starts RFID communication with the RFID tag 20 using the RFID antenna selected by the RFID antenna selection control (step S43), and monitors whether the RFID communication is terminated. If it is determined that the RFID communication is terminated (“YES” in step S44), the reading counter is incremented (step S45), and the incremented reading counter reaches the set number. If it is determined whether the incremented reading counter has not reached the set number ("NO" in step S46), the process returns to step S41 described above, and steps S41 to S46 are performed. Repeat.

  On the other hand, when the portable RFID reader / writer 1 determines that the incremented number-of-reads counter has reached the set number ("YES" in step S46), the portable RFID reader / writer 1 proceeds to the above-described wireless LAN antenna selection control (step S46). In step S47, the wireless LAN antenna selected by the wireless LAN antenna selection control is connected to the access point 21 (step S48), and the series of processing ends.

  With the process described above, in the portable RFID reader / writer 1, when performing batch reading and transfer, the RFID communication process and the wireless LAN communication process are performed in cascade, so that the wireless communication is performed immediately after the RFID communication is completed. By performing LAN antenna selection control, the higher one of the reception electric field strengths of the first wireless LAN antenna 9a and the second wireless LAN antenna 9b is selected as the operating antenna.

  As described above, according to the first embodiment, in the portable RFID reader / writer 1, the first RFID antenna 8 a is arranged along the Y-axis direction, and the second RFID antenna 8 b is arranged in the Z-axis direction. And the first wireless LAN antenna 9a is disposed along the Y-axis direction, and the second wireless LAN antenna 9b is disposed along the X-axis direction. The wavefront and the plane of polarization formed by the second wireless LAN antenna 9b can be orthogonal to each other. The plane of polarization formed by the second RFID antenna 8b and the first wireless LAN antenna 9a and the second wireless LAN antenna 9b The polarization plane formed by one of them can be orthogonal, and communication performance appropriate for each other can be achieved without degrading each other's communication performance in RFID communication and wireless LAN communication. It can be ensured.

  In the above-described embodiment, as a combination of two wireless LAN antennas, the element axis is arranged along the Y-axis direction and the element axis is arranged along the X-axis direction. The combination with the second wireless LAN antenna 9b is described, but the element axis is arranged along the Y-axis direction and the element axis is arranged along the Z-axis direction. The second wireless LAN antenna may be a combination, or the element axis may be arranged along the X-axis direction, and the first wireless LAN antenna and the element axis may be arranged along the Z-axis direction. It may be a combination of the second wireless LAN antennas.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIG. In addition, description is abbreviate | omitted about the same part as above-mentioned 1st Embodiment, and a different part is demonstrated. In the first embodiment described above, the RFID communication module 8 is connected to the two RFID antennas 8a and 8b, and the wireless LAN communication module 9 is connected to the two wireless LAN antennas 9a and 9b. However, in the second embodiment, the RFID communication module 8 is connected to one RFID antenna, and the wireless LAN communication module 9 is connected to one wireless LAN antenna.

  That is, in the portable RFID reader / writer 31, the RFID communication module 8 is connected to the RFID antenna 8c in which the axis of the element is arranged along the Y-axis direction, and the wireless LAN communication module 9 is connected to the axis of the element. Is connected to the wireless LAN antenna 9c arranged along the Z-axis direction. In this case, RFID antenna control and wireless LAN antenna control are not performed.

  According to the second embodiment, in the portable RFID reader / writer 41, the RFID antenna 8c is arranged along the Y-axis direction, and the wireless LAN antenna 9c is arranged along the Z-axis direction, so that the RFID antenna 8c is formed. The plane of polarization to be formed and the plane of polarization formed by the wireless LAN antenna 9c can be orthogonal to each other, and appropriate communication performance can be ensured without degrading each other's communication performance in RFID communication and wireless LAN communication. it can.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIG. In addition, description is abbreviate | omitted about the same part as above-mentioned 1st Embodiment, and a different part is demonstrated. In the third embodiment, the RFID communication module 8 is connected to one RFID antenna, and the wireless LAN communication module 9 is connected to two wireless LAN antennas.

  That is, in the portable RFID reader / writer 41, the RFID communication module 8 is connected to the RFID antenna 8d in which the element axis is arranged along the Y-axis direction, and the wireless LAN communication module 9 is connected to the element axis. Are connected to the first wireless LAN antenna 9d disposed along the Y-axis direction and the second wireless LAN antenna 9e disposed along the X-axis direction. In this case, the RFID antenna control is not performed, but the wireless LAN antenna control is performed to operate the first wireless LAN antenna 9d and the second wireless LAN antenna 9e having the higher received electric field strength. Select as antenna.

  According to the third embodiment, in the portable RFID reader / writer 41, the RFID antenna 8d is disposed along the Y-axis direction, the first wireless LAN antenna 9d is disposed along the Y-axis direction, and the second Since the wireless LAN antenna 9e is arranged along the X-axis direction, the polarization plane formed by the RFID antenna 8d and the polarization plane formed by the second wireless LAN antenna 9e can be orthogonalized, and RFID communication and wireless LAN communication can be performed. Therefore, appropriate communication performance can be ensured without reducing each other's communication performance.

  In this case as well, the first wireless LAN antenna in which the axis of the element is arranged along the Y-axis direction and the axis of the element are arranged along the Z-axis direction in the same manner as in the first embodiment described above. The second wireless LAN antenna may be a combination, or the element axis may be arranged along the X-axis direction, and the first wireless LAN antenna and the element axis may be arranged along the Z-axis direction. It may be a combination of the second wireless LAN antennas.

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described with reference to FIG. In addition, description is abbreviate | omitted about the same part as above-mentioned 1st Embodiment, and a different part is demonstrated. In the fourth embodiment, the RFID communication module 8 is connected to two RFID antennas, and the wireless LAN communication module 9 is connected to one wireless LAN antenna.

  That is, in the portable RFID reader / writer 51, the RFID communication module 8 includes the first RFID antenna 8e in which the element axis is arranged along the Y-axis direction and the element axis is arranged in the Z-axis direction. The wireless LAN communication module 9 is connected to a wireless LAN antenna 9f in which the element axis is disposed along the Z-axis direction. In this case, the wireless LAN antenna control is not performed. However, by performing the RFID antenna control, one of the first RFID antenna 8e and the second RFID antenna 8f having the higher RFID tag response level is operated antenna. To select.

  According to the fourth embodiment, in the portable RFID reader / writer 51, the first RFID antenna 8e is disposed along the Y-axis direction, the second RFID antenna 8f is disposed along the Z-axis direction, and wireless Since the LAN antenna 9f is arranged along the Z-axis direction, the polarization plane formed by the first RFID antenna 8e and the polarization plane formed by the wireless LAN antenna 9f can be orthogonalized, and RFID communication and wireless LAN communication can be performed. Therefore, it is possible to ensure appropriate communication performance without degrading each other's communication performance. In this case, it may be a wireless LAN antenna in which the axis of the element is arranged along the Y-axis direction.

(Other embodiments)
The present invention is not limited to the above-described embodiment, and can be modified or expanded as follows.
The arrangement mode of the RFID antenna and the wireless LAN antenna may be another arrangement mode as long as the polarization plane formed by the RFID antenna and the polarization plane formed by the wireless LAN antenna are orthogonal to each other.

The 1st Embodiment of this invention is a figure which shows the arrangement | positioning aspect of an antenna roughly Functional block diagram showing electrical configuration Flow chart (Part 1) Flow chart (Part 2) Flow chart (part 3) Flow chart (Part 4) The figure which shows the 2nd Embodiment of this invention and shows the arrangement | positioning aspect of an antenna roughly The figure which shows the 3rd Embodiment of this invention and shows the arrangement | positioning aspect of an antenna roughly The 4th Embodiment of this invention is a figure which shows the arrangement | positioning aspect of an antenna roughly

Explanation of symbols

  In the drawings, 1 is a portable RFID reader / writer, 2 is a housing, 3a is a flat surface portion (horizontal surface portion), 4a is a flat surface portion (horizontal surface portion), 8 is an RFID communication module (RFID communication means, RFID antenna switching means), 8a to 8f are RFID antennas, 9 is a wireless LAN communication module (wireless LAN communication means, wireless LAN antenna switching means), 9a to 9f are wireless LAN antennas, 20 is an RFID tag, 21 is an access point (external wireless device), 31 Is a portable RFID reader / writer, 41 is a portable RFID reader / writer, and 51 is a portable RFID reader / writer.

Claims (9)

In a portable RFID reader / writer in which an RFID communication unit that performs RFID communication with an RFID tag and a wireless LAN communication unit that performs wireless LAN communication with an external wireless device are provided in a housing.
The RFID antenna having a linear polarization characteristic connected to the RFID communication means and the wireless LAN antenna having a linear polarization characteristic connected to the wireless LAN communication means have orthogonal polarization planes formed by each. A portable RFID reader / writer characterized by being arranged in such a relationship. The portable RFID reader / writer according to claim 1,
The casing is formed in a long shape, two antennas are provided as the RFID antenna, and two antennas are provided as the wireless LAN antenna,
The two RFID antennas are arranged on a horizontal plane parallel to the horizontal plane portion of the casing and in a horizontal plane parallel to the horizontal plane section of the casing and an antenna disposed along a direction orthogonal to the longitudinal direction of the casing. Composed of a combination with antennas arranged along the orthogonal direction,
The two wireless LAN antennas are located on a horizontal plane parallel to a horizontal plane portion of the casing and are arranged along a direction orthogonal to a longitudinal direction of the casing, and a horizontal plane parallel to the horizontal plane section of the casing. Combination with an antenna disposed along a direction orthogonal to the antenna, an antenna disposed in a horizontal plane parallel to the horizontal plane portion of the casing and along the longitudinal direction of the casing, and a horizontal plane portion of the casing Combination with an antenna arranged along a direction perpendicular to a horizontal plane parallel to the antenna, and an antenna arranged along a longitudinal direction of the casing on a horizontal plane parallel to the horizontal plane portion of the casing. A portable RFID carrier comprising any one of a combination with an antenna arranged on a horizontal plane parallel to a horizontal plane portion of the body and perpendicular to the longitudinal direction of the casing. Daraita. The portable RFID reader / writer according to claim 1,
The casing is formed in a long shape, and one antenna is provided as the RFID antenna and one antenna is provided as the wireless LAN antenna.
The one RFID antenna is disposed along a direction perpendicular to the longitudinal direction of the casing in a horizontal plane parallel to the horizontal plane portion of the casing,
The portable RFID reader / writer, wherein the one wireless LAN antenna is arranged along a direction orthogonal to a horizontal plane parallel to a horizontal plane portion of the casing. The portable RFID reader / writer according to claim 1,
The casing is formed in a long shape, and one antenna is provided as the RFID antenna and two antennas are provided as the wireless LAN antenna.
The one RFID antenna is disposed along a direction perpendicular to the longitudinal direction of the casing in a horizontal plane parallel to the horizontal plane portion of the casing,
The two wireless LAN antennas are located on a horizontal plane parallel to a horizontal plane portion of the casing and are arranged along a direction orthogonal to a longitudinal direction of the casing, and a horizontal plane parallel to the horizontal plane section of the casing. Combination with an antenna disposed along a direction orthogonal to the antenna, an antenna disposed in a horizontal plane parallel to the horizontal plane portion of the casing and along the longitudinal direction of the casing, and a horizontal plane portion of the casing Combination with an antenna arranged along a direction perpendicular to a horizontal plane parallel to the antenna, and an antenna arranged along a longitudinal direction of the casing on a horizontal plane parallel to the horizontal plane portion of the casing. A portable RFID carrier comprising any one of a combination with an antenna arranged on a horizontal plane parallel to a horizontal plane portion of the body and perpendicular to the longitudinal direction of the casing. Daraita. The portable RFID reader / writer according to claim 1,
The casing is formed in a long shape, two antennas are provided as the RFID antenna, and one antenna is provided as the wireless LAN antenna.
The two RFID antennas are arranged on a horizontal plane parallel to the horizontal plane portion of the casing and in a horizontal plane parallel to the horizontal plane section of the casing and an antenna disposed along a direction orthogonal to the longitudinal direction of the casing. Composed of a combination with antennas arranged along the orthogonal direction,
The one wireless LAN antenna is disposed along a direction orthogonal to a horizontal plane parallel to the horizontal plane portion of the casing, or in a horizontal plane parallel to the horizontal plane portion of the casing and in a longitudinal direction of the casing. A portable RFID reader / writer, which is arranged along a direction orthogonal to each other. The portable RFID reader / writer according to claim 2,
A wireless LAN antenna switching means for measuring the received electric field strength of each of the two wireless LAN antennas and selectively switching one of the two wireless LAN antennas as an operating antenna based on the measurement result;
In the aspect in which the wireless LAN communication means performs wireless LAN communication with an external wireless device every time the RFID communication means performs RFID communication with the RFID tag, the wireless LAN antenna switching means is the RFID communication means. Each time the RFID is in RFID communication with the RFID tag, the received electric field strength of each of the two wireless LAN antennas is measured, and one of the two wireless LAN antennas is operated based on the measurement result. A portable RFID reader / writer characterized by being selectively switched as follows. The portable RFID reader / writer according to claim 2,
A wireless LAN antenna switching means for measuring the received electric field strength of each of the two wireless LAN antennas and selectively switching one of the two wireless LAN antennas as an operating antenna based on the measurement result;
In the aspect in which the wireless LAN communication means performs wireless LAN communication with an external wireless device every time the RFID communication means performs RFID communication with the RFID tag, the wireless LAN antenna switching means is the RFID communication means. Immediately after completing RFID communication with the RFID tag, the received electric field strength of each of the two wireless LAN antennas is measured, and one of the two wireless LAN antennas is operated based on the measurement result. A portable RFID reader / writer characterized by being selectively switched as an antenna. The portable RFID reader / writer according to claim 2,
RFID tag switching means for measuring the RFID tag response level of each of the two RFID antennas and selectively switching one of the two RFID antennas as an operating antenna based on the measurement result,
In the aspect in which the wireless LAN communication unit performs wireless LAN communication with an external wireless device every time the RFID communication unit performs RFID communication with the RFID tag, the wireless LAN communication unit Selects one of the two wireless LAN antennas whose polarization planes are orthogonal to each other, and then measures the RFID tag response level of each of the two RFID antennas. A portable RFID reader / writer characterized in that one of antennas is selectively switched as an operating antenna based on the measurement result. The portable RFID reader / writer according to claim 2,
A wireless LAN antenna switching means for measuring the received electric field strength of each of the two wireless LAN antennas and selectively switching one of the two wireless LAN antennas as an operating antenna based on the measurement result;
The wireless LAN antenna switching means performs wireless LAN communication between the wireless LAN communication means and an external wireless device after the RFID communication means performs RFID communication for a preset number of times with the RFID tag. In the embodiment, immediately after the RFID communication means ends RFID communication for a set number of times with the RFID tag, the received electric field strength of each of the two wireless LAN antennas is measured, and the two wireless LAN antennas are measured. A portable RFID reader / writer characterized in that one of them is selectively switched as an operating antenna based on the measurement result.

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