JP2015041329A - Signal measurement system, non-contact ic card reader/writer, and signal measurement method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a signal measurement system configured to externally acquire signal data transmission timing of signal data in an RF signal to be transmitted from a non-contact IC card reader/writer.SOLUTION: A light-emitting unit 120 arranged on an outer surface of a housing 110 of a non-contact IC card reader/writer 100 externally outputs a light-emitting signal H which blinks in synchronization with transmission timing of signal data. A measurement unit 500 acquires an RF signal F transmitted from an antenna 104 to a non-contact IC card 200 by means of a measurement coil 300. A light-receiving apparatus 400 receives the light-emitting signal H and acquires it as a synchronization signal S including a signal in synchronization with transmission timing of the signal data, uses the synchronization signal S as a trigger, and measures the signal data between the non-contact IC card reader/writer 100 and the non-contact IC card 200, on the basis of the extracted signal data included in the RF signal F.

Description

  The present invention relates to a signal measurement system, a non-contact IC card reader / writer, and a signal measurement method.

  The non-contact IC card reader / writer superimposes signal data for transmission / reception with the non-contact IC card on a carrier wave and transmits / receives it as an RF (Radio Frequency) signal. For example, Japanese Patent Application Laid-Open No. 2000-242739 of Patent Document 1 discloses a non-contact IC card reader capable of reducing power loss and heat generation in transmission and reception and widening a communication distance when a non-contact IC card is close in the communication range. A writer device is described. When a communication failure occurs between the non-contact IC card reader / writer and the non-contact IC card, a mechanism for measuring signal data transmitted / received by an RF signal is required. That is, a signal measurement system including a measuring device for measuring signal data transmitted and received by an RF signal is required. The measuring device, for example, induces a voltage in a measurement coil by using an RF signal from a non-contact IC card reader / writer, and thereby the signal data contained in the RF signal is normal between the non-contact IC card. Monitor whether it is being sent or received.

  FIG. 5 is a system configuration diagram of a conventional signal measurement system configured by attaching a measuring instrument for monitoring signal data transmitted and received by a non-contact IC card reader / writer. As shown in FIG. 5, in the conventional signal measurement system, a measurement coil 300 is arranged at a position close to the antenna 104 installed in the casing 110 ′ of the non-contact IC card reader / writer 100 ′, and a non-contact IC card reader is provided. A voltage is induced in the measurement coil 300 by the RF signal F transmitted and received between the writer 100 ′ and the non-contact IC card 200, and the voltage induced in the measurement coil 300 is taken into the measuring device 500 side. . The measuring device 500 ′ extracts and monitors signal data transmitted and received between the non-contact IC card reader / writer 100 ′ and the non-contact IC card 200 from the voltage induced in the measurement coil 300, thereby preventing communication failure. The presence or absence of occurrence can be determined.

JP 2000-242739 A

  In the conventional signal measurement system shown in FIG. 5, the RF signal F transmitted / received between the non-contact IC card reader / writer 100 ′ and the non-contact IC card 200 includes a carrier wave in addition to the signal data. Yes. Since the carrier wave is also used for supplying power to the non-contact IC card 200, it is continuously transmitted from the non-contact IC card reader / writer 100 ′ as long as it is in communication regardless of the presence or absence of signal data. Has been. Therefore, when a communication failure occurs in communication between the non-contact IC card reader / writer 100 ′ and the non-contact IC card 200, the measuring device 500 ′ causes the non-contact IC card reader / writer 100 ′ and the non-contact IC card 200 to When the communication data from any of the communication directions is examined to determine whether a communication failure has occurred, it is determined at which timing of the RF signal F the signal data from the non-contact IC card reader / writer 100 ′ is transmitted. It is necessary to.

  However, the generation part of the signal data from the non-contact IC card reader / writer 100 'exists inside the casing 110'. The manufacturer of the non-contact IC card reader / writer 100 ′ sends a signal data transmission timing signal from the internal circuit through the lead wire before covering the internal circuit portion with the cover of the housing 110 ′ in the final assembly process. The transmission timing signal was taken out and input to the measuring device 500 ′ (this lead wire is not drawn in FIG. 5). In the measuring instrument 500 ′, a signal transmitted and received between the non-contact IC card reader / writer 100 ′ and the non-contact IC card 200 from the voltage induced in the measurement coil 300 based on the transmission timing signal thus supplied. By extracting and monitoring data, it was determined whether or not a communication failure occurred. On the other hand, it is difficult for a user other than the manufacturer of the contactless IC card reader / writer 100 ′ to detect the transmission timing of the signal data from the contactless IC card reader / writer 100 ′ from the outside of the housing 110 ′. . Therefore, when measuring the signal data generated by the non-contact IC card reader / writer 100 ′, the housing 110 ′ is disassembled so that the signal data generation site can be directly accessed. is necessary. However, a place where communication failure has occurred is generally a place where facilities are not prepared. In such a place, it is difficult to disassemble the casing 110 ', and it is difficult to quickly respond to communication failure.

(Object of the present invention)
The present invention has been made in view of the above circumstances, and signal data between a non-contact IC card reader / writer and a non-contact IC card, even if it is not a manufacturer of the non-contact IC card reader / writer. In the communication state between the non-contact IC card reader / writer and the non-contact IC card, the non-contact IC card reader / writer can be measured without changing the non-contact IC card reader / writer. It is an object of the present invention to provide a signal measurement system, a non-contact IC card reader / writer, and a signal measurement method that can acquire the transmission timing of signal data in an RF signal transmitted from the outside.

  In order to solve the above-described problems, the signal measurement system, the non-contact IC card reader / writer, and the signal measurement method according to the present invention mainly adopt the following characteristic configuration.

  (1) A signal measurement system according to the present invention acquires an RF (Radio Frequency) signal transmitted / received between a non-contact IC card reader / writer and a non-contact IC card, whereby the non-contact IC card reader / writer and the non-contact IC card reader / writer A signal measurement system including a measuring device for measuring signal data exchanged with a non-contact IC card, wherein the non-contact IC card reader / writer flashes in synchronization with the transmission timing of the signal data A light emitting unit for outputting a signal to the outside is provided on the outer surface of the housing, and the measuring device receives the light emission signal output from the light emitting unit by a light receiving device and converts it into an electrical signal, and synchronizes with the transmission timing of the signal data. The electrical signal is output from the light receiving device as a synchronization signal including a signal to be used, and the synchronization signal output from the light receiving device is used as a trigger. The signal data included in the RF signal is extracted, and the signal data between the non-contact IC card reader / writer and the non-contact IC card is measured based on the extracted signal data. .

  (2) A non-contact IC card reader / writer according to the present invention is a non-contact IC card reader / writer which modulates signal data exchanged with a non-contact IC card into an RF (Radio Frequency) signal and transmits / receives the signal data. A light emitting unit that outputs a light emission signal blinking in synchronization with the transmission timing of signal data to the outside is provided on the outer surface of the housing.

  (3) In the signal measuring method according to the present invention, an RF (Radio Frequency) signal transmitted and received between the non-contact IC card reader / writer and the non-contact IC card is obtained by a measuring instrument, so that the non-contact IC card reader A signal measurement method for measuring signal data exchanged between a writer and the non-contact IC card, wherein the non-contact IC card reader / writer receives the signal data from a light emitting unit provided on an outer surface of a housing. A light emission signal that blinks in synchronization with the transmission timing is output to the outside, and the measuring device receives the light emission signal output from the light emitting unit and converts it into an electrical signal, and the transmission timing of the signal data A synchronization signal including a signal to be synchronized is generated, and the signal data included in the RF signal is extracted using the generated synchronization signal as a trigger. The signal data between the non-contact IC card reader / writer and the non-contact IC card is measured based on the extracted signal data.

  According to the present invention, it is possible to acquire the transmission timing of signal data in an RF signal transmitted by a non-contact IC card reader / writer without changing the non-contact IC card reader / writer.

It is a system configuration figure showing an example of the system configuration of the signal measurement system concerning the present invention. It is a block block diagram which shows an example of an internal structure of the non-contact IC card reader / writer in the signal measurement system of FIG. FIG. 2 is a circuit diagram illustrating an example of a specific circuit configuration in a light emitting unit that outputs a light emission signal from the non-contact IC card reader / writer in FIG. 1. 2 is a time chart for explaining the timing relationship of signals output from main parts of the non-contact IC card reader / writer of FIG. 1. It is a system configuration diagram of a conventional signal measurement system configured by attaching a measuring instrument for monitoring signal data transmitted and received by a non-contact IC card reader / writer.

  Preferred embodiments of a signal measurement system, a non-contact IC card reader / writer, and a signal measurement method according to the present invention will be described below with reference to the accompanying drawings. In the following description, a signal measurement system, a non-contact IC card reader / writer, and a signal measurement method according to the present invention will be described. A signal measurement program capable of executing control steps for controlling the signal measurement method by a computer. Needless to say, the signal measurement program may be recorded on a computer-readable recording medium.

(Features of the present invention)
Prior to the description of the embodiments of the present invention, an outline of the features of the present invention will be described first. The main feature of the present invention is to realize a non-contact IC card reader / writer that facilitates measurement of signal data and is easy to use in communication between the non-contact IC card reader / writer and the non-contact IC card. Yes.

  As a specific implementation means of the present invention, the non-contact IC card reader / writer includes a light emitting unit on the outer surface of the housing, and the light emitting unit is synchronized with a transmission timing of signal data communicated with the non-contact IC card. By outputting a flashing light emission signal to the outside of the housing, signal data can be easily measured. In other words, the light emitting unit flashes in synchronization with the transmission timing of the signal data transmitted from the non-contact IC card reader / writer to the non-contact IC card, that is, the light emission flashes in accordance with the High / Low state of the signal data. The signal is output to the outside of the housing as a signal indicating the communication state of the non-contact IC card reader / writer.

  Furthermore, the measuring device installed to measure the RF signal transmitted from the non-contact IC card reader / writer to the non-contact IC card includes a light receiving device, and the light receiving device is a housing of the non-contact IC card reader / writer. A light emission signal (flashing optical signal) emitted from a light emitting unit provided on the outer surface is received, converted into an electrical signal, and a synchronization signal including a signal synchronized with the transmission timing of the signal data to the measuring instrument. Send. The measuring device that has received the synchronization signal from the light receiving device generates a trigger signal for detecting signal data included in the RF signal transmitted from the non-contact IC card reader / writer, and the trigger signal causes the RF signal to be included in the RF signal. Therefore, the signal data of the non-contact IC card reader / writer and the non-contact IC card can be easily measured and the usability can be improved. The signal data from the non-contact IC card is measured by monitoring the RF signal for a predetermined time from the transmission timing of the non-contact IC card reader / writer.

(Configuration example of embodiment of the present invention)
Next, an example of the system configuration of the signal measurement system according to the present invention will be described in detail with reference to FIG. FIG. 1 is a system configuration diagram showing an example of a system configuration of a signal measurement system according to the present invention. The signal measurement system shown in FIG. 1 includes a non-contact IC card reader / writer 100, a non-contact IC card 200, and a measuring instrument 500, similar to the conventional signal measurement system shown in FIG. The measuring device 500 arranges the measuring coil 300 at a position close to the antenna 104 installed in the housing 110 of the non-contact IC card reader / writer 100, and between the non-contact IC card reader / writer 100 and the non-contact IC card 200. The voltage is induced in the measuring coil 300 by the RF signal F transmitted / received in FIG.

  Further, the signal measurement system shown in FIG. 1 differs from the conventional signal measurement system shown in FIG. 5 in that the measuring device 500 is connected to the non-contact IC card reader / writer 100 from the RF signal F captured by the measuring coil 300. Light emission that flashes on the outer surface of the housing 110 of the non-contact IC card reader / writer 100 in synchronization with the transmission timing of the signal data so that signal data transmitted to and received from the non-contact IC card 200 can be extracted. By installing the light emitting unit 120 that outputs the signal H, the transmission timing of the signal data to be transmitted is output to the outside.

  On the other hand, the light receiving device 400 is connected to the measuring instrument 500 side. The light receiving device 400 is disposed at a position close to the light emitting unit 120 of the non-contact IC card reader / writer 100, receives the light emission signal H output from the light emitting unit 120, converts it into an electrical signal, and measures it as a synchronization signal S. To the device 500. The measuring device 500 generates a trigger signal for extracting signal data from the RF signal F received from the measuring coil 300 based on the synchronization signal S transmitted from the light receiving device 400, and is included in the RF signal F. Signal data can be extracted. The measurement of signal data from the non-contact IC card can be extracted by monitoring the RF signal for a predetermined time from the transmission timing of the non-contact IC card reader / writer.

  Next, an example of the internal configuration of the non-contact IC card reader / writer 100 shown in FIG. 1 will be described in more detail with reference to FIG. FIG. 2 is a block diagram showing an example of the internal configuration of the contactless IC card reader / writer 100 in the signal measurement system of FIG. 1, and a transmission timing display for displaying and outputting information indicating the transmission timing of signal data to the outside. An example of the internal configuration of the functioning non-contact IC card reader / writer is shown.

  As shown in FIG. 2, the non-contact IC card reader / writer 100 includes at least a control unit 101, a modulation circuit 102, an amplification circuit 103, an antenna 104, a reception circuit 105, and a light emitting unit 120. When the control unit 101 of the non-contact IC card reader / writer 100 in FIG. 2 shifts to a state in communication with the non-contact IC card 200, the control unit 101 displays a display signal A indicating that the communication is in progress to the light emitting unit 120. The transmission data signal B indicating the signal data to be transmitted is generated and output to the modulation circuit 102 and the light emitting unit 120, and the carrier wave C is generated to the modulation circuit 102. Output.

  The modulation circuit 102 generates a transmission signal D obtained by superimposing the transmission data signal B on the carrier wave C output from the control unit 101, and outputs the transmission signal D to the amplification circuit 103. The amplification circuit 103 generates a transmission amplification signal E obtained by amplifying the transmission signal D output from the modulation circuit 102 with a preset amplification factor, and outputs the transmission amplification signal E to the antenna 104. The antenna 104 emits the transmission amplification signal E from the amplification circuit 103 to the outside as an RF signal F. The non-contact IC card 200 that has received the RF signal F emitted from the antenna 104 acquires driving power from the carrier wave of the received RF signal F, and according to the signal data included in the RF signal F. Then, the load in the non-contact IC card 200 is switched, and the load fluctuation is superimposed on the RF signal F and sent back to the non-contact IC card reader / writer 100.

  When the RF signal F from the non-contact IC card 200 is received via the antenna 104, the receiving circuit 105 of the non-contact IC card reader / writer 100 indicates the load fluctuation included in the RF signal F together with the transmission amplification signal E. A reception demodulation operation for extracting information is performed, and a reception data signal G from the non-contact IC card 200 is output to the control unit 101, and communication is terminated.

  On the other hand, the light emitting unit 120 of the non-contact IC card reader / writer 100 outputs the light emission signal H that is turned on by the display signal A indicating the communication state, and then transmits the transmission data signal output from the control unit 101. The light emission state of the light emission signal H is blinked in synchronization with ON / OFF of B, and the light emission signal H is output to the outside of the non-contact IC card reader / writer 100 as the blinking light emission signal H. Therefore, the blinking state of the light emission signal H output from the light emitting unit 120 blinks in synchronization with the transmission timing of signal data to be transmitted from the non-contact IC card reader / writer 100, This means that the data transmission timing is notified. The light receiving device 400 disposed in the vicinity of the light emitting unit 120 receives a light emission signal H (an optical signal blinking in synchronization with a transmission data signal B indicating signal data to be transmitted) output from the light emitting unit 120. Then, the signal is converted into an electric signal and is sent to the measuring instrument 500 as a synchronizing signal S including a signal synchronized with the transmission timing of the signal data included in the RF signal F emitted from the antenna 104 of the non-contact IC card reader / writer 100. To send.

(Description of operation of embodiment)
Next, the operation of the signal measurement system shown in FIGS. 1 and 2 will be described in detail with reference to FIGS. 3 and 4. FIG. 3 is a circuit diagram showing an example of a specific circuit configuration in the light emitting unit 120 that outputs the light emission signal H from the non-contact IC card reader / writer 100 of FIG. Here, the light emission signal H flashes in synchronization with the transmission timing of the signal data to be transmitted from the non-contact IC card reader / writer 100, thereby notifying the transmission timing of the signal data to the outside as described above. ing.

  FIG. 4 is a time chart for explaining the timing relationship of signals output from main parts of the non-contact IC card reader / writer 100 of FIG. That is, FIG. 4A is a time chart of the RF signal F emitted from the antenna 104, and FIG. 4B is a diagram of the light emitting unit 120 and the modulation circuit 102 from the control unit 101 inside the housing 110. FIG. 4C is a time chart of the output transmission data signal B. FIG. 4C is a time chart of the display signal A output from the control unit 101 inside the housing 110 to the light emitting unit 120. 4 (D) is a time chart of the light emission signal H output from the light emitting unit 120.

  First, an example of the operation of the light emitting unit 120 will be described in detail with reference to the circuit diagram of the light emitting unit 120 of FIG. As an example, in the circuit configuration of the light emitting unit 120 shown in FIG. 3, the light emitting unit 120 is a display signal switch 121 that is switched on / off by a display signal A, and an LED (Light Emitting Diode) that outputs a flashing light emitting signal H to the outside. ) 122, and a transmission data signal switch 123 for switching ON / OFF by the transmission data signal B is connected in series. In an initial state before communication is started, the display signal A and the transmission data signal B output from the control unit 101 are both in the high state, the display signal switch 121 is in the OFF state, while the transmission data signal is transmitted. The switch 123 is in an ON state. Therefore, in the initial state, no current flows through the LED 122 and the light emission signal H is extinguished.

  Next, when reaching the start of communication, the display signal A is switched from High to Low state and output from the control unit 101, the display signal switch 121 is switched to ON state, the power supply voltage Vcc is applied to both ends of the LED 122, and the LED 122 A current flows through the. Therefore, the light emission signal H output from the LED 122 is switched to a lit state.

  Thereafter, when signal data to be transmitted is generated and the transmission data signal B is output from the control unit 101, when the transmission data signal B is High active, the transmission data signal switch 123 is turned on and the LED 122 is turned on. On the other hand, when the transmission data signal B is active low, the transmission data signal switch 123 is turned OFF and the current does not flow to the LED 122. Therefore, the light emission signal H output from the LED 122 blinks in synchronization with the High and Low states of the transmission data signal B. A current limiting resistor 124 is inserted between the LED 122 and the transmission data signal switch 123.

  When the communication is completed, the display signal A is switched from Low to High and output from the control unit 101. Therefore, the display signal switch 121 is switched from ON to OFF, and no current flows through the LED 122. Therefore, the light emission signal H output from the LED 122 is switched to the extinguished state.

Next, with reference to the time chart of FIG. 4, the timing relationship of each signal of the main part of the non-contact IC card reader / writer 100 will be further described. In the time chart of FIG. 4, when communication is started at time t ₀ , as shown in FIG. 4A, the RF signal F in a state where the carrier wave C generated by the control unit 101 in the housing 110 is modulated and amplified. Is emitted from the antenna 104, and as shown in FIG. 4C, the display signal A output from the control unit 101 in the housing 110 to the light emitting unit 120 is switched from High to Low. The display signal switch 121 is turned on, and the light emission signal H output from the light emitting unit 120 is switched to the lighting state and output to the outside as shown in FIG.

Thereafter, at time t _{1 to} t ₆ , the control unit 101 tries to transmit signal data, and the transmission data signal B output from the control unit 101 to the modulation circuit 102 is transmitted as shown in FIG. When the Low / High state is switched, the transmission data signal switch 123 is switched to the OFF / ON state in synchronization with the Low / High state of the transmission data signal B, and the light emission signal H output from the light emitting unit 120 is As shown in 4 (D), the light extinction / lighting state is switched. That is, at times t ₁ to t _{6 at} which the transmission data signal B is transmitted, as shown in FIGS. 4B and 4D, in synchronization with the transmission timing of the signal data included in the RF signal F, The light emission signal H output from the light emitting unit 120 blinks. Therefore, by detecting the switching from the lighting signal H to the extinguished state in the light receiving device 400, the measuring device 500 is used as a synchronization signal S for measuring the signal data included in the RF signal F. Can be output.

Thereafter, when communication is completed at time t ₇ , the carrier wave C is not output from the control unit 101 in the housing 110, and the RF signal F is not emitted from the antenna 104 as shown in FIG. As shown in FIG. 4C, the display signal A output from the control unit 101 in the housing 110 to the light emitting unit 120 is switched from Low to High, and the display signal switch 121 is turned off. Thus, the light emission signal H output from the light emitting unit 120 is switched to the extinguished state and output to the outside as shown in FIG. Note that the time chart of FIG. 4 does not show signal data from the non-contact IC card. In the above embodiment, the light emitting unit is turned off at the transmission timing of the signal data from the non-contact IC card reader / writer. Conversely, at the transmission timing of the signal data from the non-contact IC card reader / writer, The light emitting unit may be turned on.

  As described above, the light emission signal H blinks on the outer surface of the housing 110 of the non-contact IC card reader / writer 100 in synchronization with the transmission timing of the signal data (transmission data signal B) to be transmitted and output to the outside. By including the light emitting unit 120 that performs the above, it is possible to easily acquire the transmission timing of the signal data from the outside without directly accessing the circuit inside the housing 110. Further, a light receiving device 400 connected to the measuring device 500 is disposed at a position close to the light emitting unit 120, and the light receiving device 400 receives the light emission signal H output from the light emitting unit 120 to obtain signal data. It is also possible to generate a synchronization signal S as a trigger for extracting the transmission timing of the signal and output it to the measuring device 500. In the measuring device 500 that measures the signal data included in the RF signal F, the RF The signal data included in the signal F can be extracted at an accurate timing, and the presence or absence of communication failure from the non-contact IC card reader / writer 100 can be accurately determined.

  In the circuit configuration of the display unit 120 illustrated in FIG. 3, the case where an LED (Light Emitting Diode) is used as a light emitting element for outputting the light emission signal H from the light emitting unit 120 to the outside is illustrated. In addition, a light bulb, an organic EL (Organic Electro-Luminescence), or the like may be used.

(Explanation of effect of embodiment)
As described in detail above, the following effects are obtained in the present embodiment.

  First, when acquiring the transmission timing of the signal data transmitted from the non-contact IC card reader / writer 100, it is not necessary to newly add a configuration other than the object to be measured to the measurement environment of the signal data. Signal data transmitted and received between the non-contact IC card reader / writer 100 and the non-contact IC card 200 can be measured without affecting the RF signal F transmitted from the antenna 104 of the reader / writer 100.

  Secondly, information notifying the transmission timing of the signal data transmitted from the non-contact IC card reader / writer 100 is output to the outside of the housing 110 of the non-contact IC card reader / writer 100 as the light emission signal H from the light emitting unit 120. Therefore, the transmission timing of the signal data can be easily acquired even from the outside of the housing 110 without disassembling the housing 110 of the non-contact IC card reader / writer 100.

  Thirdly, information notifying the transmission timing of the signal data transmitted from the non-contact IC card reader / writer 100 is output to the outside of the housing 110 of the non-contact IC card reader / writer 100 as the light emission signal H from the light emitting unit 120. Therefore, even a user other than the manufacturer of the contactless IC card reader / writer 100 can easily acquire the transmission timing of the signal data.

  The configuration of the preferred embodiment of the present invention has been described above. However, it should be noted that such embodiments are merely examples of the present invention and do not limit the present invention in any way. Those skilled in the art will readily understand that various modifications and changes can be made according to a specific application without departing from the gist of the present invention.

A display signal B transmission data signal C carrier wave D transmission signal E transmission amplification signal F RF signal G reception data signal H emission signal S synchronization signal Vcc power supply voltage 100 contactless IC card reader / writer 101 control unit 102 modulation circuit 103 amplification circuit 104 Antenna 105 Reception circuit 110 Case 120 Light emitting unit 121 Display signal switch 122 LED
123 Transmission data signal switch 124 Current limiting resistor 200 Non-contact IC card 300 Measuring coil 400 Light receiving device 500 Measuring instrument

Claims (8)

By obtaining an RF (Radio Frequency) signal transmitted and received between the non-contact IC card reader / writer and the non-contact IC card, the non-contact IC card reader / writer is exchanged between the non-contact IC card and the non-contact IC card. A signal measurement system comprising a measuring instrument for measuring signal data,
The non-contact IC card reader / writer includes a light emitting unit that outputs a light emission signal that blinks in synchronization with the transmission timing of the signal data to the outside,
The measuring device receives the light emission signal output from the light emitting unit by a light receiving device and converts it into an electric signal, and the electric signal is used as a synchronization signal including a signal synchronized with a transmission timing of the signal data. And using the synchronization signal output from the light receiving device as a trigger, the signal data included in the RF signal is extracted, and the contactless IC card reader is extracted based on the extracted signal data. A signal measurement system for measuring the signal data between a writer and the non-contact IC card.   The light emitting element that generates the light emission signal output from the light emitting unit to the outside is any one of an LED (Light Emitting Diode), an organic EL (Organic Electro-Luminescence), or a light bulb. Signal measurement system as described in.   The RF signal transmitted from the non-contact IC card reader / writer to the outside as means for acquiring the RF signal transmitted / received between the non-contact IC card reader / writer and the non-contact IC card by the measuring instrument The signal measurement system according to claim 1, wherein a measurement coil arranged at a position where a voltage is induced by is connected.   A non-contact IC card reader / writer that modulates signal data exchanged with a non-contact IC card into an RF (Radio Frequency) signal and transmits / receives the light signal that flashes in synchronization with the transmission timing of the signal data. A non-contact IC card reader / writer characterized in that a light emitting section for outputting to the outside is provided on the outer surface of the housing.   5. The light emitting element that generates the light emission signal output from the light emitting unit to the outside is any one of an LED (Light Emitting Diode), an organic EL (Organic Electro-Luminescence), or a light bulb. A non-contact IC card reader / writer as described in 1. An RF (Radio Frequency) signal transmitted and received between the non-contact IC card reader / writer and the non-contact IC card is acquired by a measuring instrument, so that the non-contact IC card reader / writer and the non-contact IC card are A signal measurement method for measuring exchanged signal data,
The non-contact IC card reader / writer outputs a light emission signal blinking in synchronization with the transmission timing of the signal data from the light emitting unit provided on the outer surface of the housing,
The measuring device receives the light emission signal output from the light emitting unit, converts the light emission signal into an electrical signal, generates a synchronization signal including a signal synchronized with a transmission timing of the signal data, and further generates the synchronization The signal data included in the RF signal is extracted using a signal for a trigger, and the non-contact IC card reader / writer and the non-contact IC card are extracted based on the extracted signal data. A signal measuring method comprising measuring signal data.   The light emitting element that generates the light emission signal output to the outside from the light emitting unit is an LED (Light Emitting Diode), an organic EL (Organic Electro-Luminescence), or a light bulb. A signal measuring method according to claim 1.   The RF signal transmitted from the non-contact IC card reader / writer to the outside as means for acquiring the signal data transmitted and received between the non-contact IC card reader / writer and the non-contact IC card. The signal measuring method according to claim 6, wherein a measuring coil disposed at a position where a voltage is induced by is connected.

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