JP6561972B2 - Reader writer - Google Patents

Description

  The present invention relates to a reader / writer that performs data communication with a tag, and more particularly to a technique for controlling an amplification factor of a carrier wave signal.

  Some reader / writers transmit a carrier wave signal modulated according to data from an antenna. The tag receives this carrier signal and demodulates it to generate data (see Patent Document 1).

  Further, in Patent Document 2, the amplitude of the carrier wave of the RFID reader is gradually increased at the start of communication, the amplitude is gradually decreased at the end of communication, and then gradually increased. The noise of the frequency component is suppressed.

JP 2012-198872 A JP 2010-182177 A

  By the way, in order to increase the communication distance between the reader / writer and the tag, it is necessary to increase the level of the carrier signal of the reader / writer. However, since an inrush current is generated immediately after the carrier signal is turned on, the voltage increases due to the inrush current when the level of the carrier signal is increased, and this large voltage exceeds the rated voltage of the circuit constituting the reader / writer. There is a risk of lowering the durability of the circuit or causing a failure. For this reason, conventionally, it has been necessary to use a circuit having a standard capable of withstanding the voltage raised by the inrush current for the reader / writer.

  In Patent Document 2, the amplitude of the carrier wave is gradually increased and decreased gradually. This is a technique for suppressing noise, and measures against inrush current are taken. Absent.

  The present invention has been made in view of the above circumstances, and an object thereof is to reduce an inrush current generated immediately after a reader / writer's carrier wave signal is turned on.

  The reader / writer according to one aspect of the present invention includes a generation unit that generates a carrier wave signal, an amplifier that amplifies the carrier wave signal generated by the generation unit, a control unit that controls amplification on / off and an amplification factor by the amplifier, Transmitting the carrier wave signal amplified by the amplifier and receiving the subcarrier signal, the carrier wave signal amplified by the amplifier and the subcarrier signal received by the antenna as a received signal, and receiving this A detector that outputs an analog signal corresponding to an envelope of the signal, and a converter that inputs the analog signal from the detector and outputs a digital signal corresponding to the analog signal, and the control unit includes When the amplifier is switched from amplification off to amplification on, the amplification factor is increased in a plurality of stages to increase the amplification of the amplifier. The one in which increased to gain a defined predetermined.

  According to the present invention, it is possible to reduce the inrush current that occurs immediately after the carrier signal of the reader / writer is turned on. For this reason, according to the present invention, it is also possible to suppress a voltage increase due to an inrush current generated at the start of carrier wave signal generation within the circuit rating.

It is a block diagram which shows one embodiment of the reader / writer of this invention. (A), (b), and (c) are timing charts showing the carrier signal before amplification, the amplified carrier signal, and the voltage that rises due to the inrush current in the reader / writer of this embodiment. (A), (b), and (c) are timing charts showing a carrier signal before amplification, an amplified carrier signal, and a voltage rising due to an inrush current in a comparative example.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a block diagram showing an embodiment of a reader / writer according to the present invention. The reader / writer 1 of the present embodiment performs data communication with a passive or active tag TG, modulates a carrier wave signal according to data, and transmits the modulated carrier wave signal to the tag. Or demodulating the subcarrier signal received from the tag TG to generate data. Similarly, the tag TG also modulates the subcarrier signal in accordance with the data, transmits the modulated subcarrier signal to the reader / writer 1, or demodulates the carrier signal received from the reader / writer 1, Or generate. Here, although the frequency of the subcarrier signal is different from the frequency of the carrier signal, even if the frequency of the subcarrier signal is the same as the frequency of the carrier signal, that is, the reader / writer 1 and the tag have the same frequency. May be sent and received.

  As shown in FIG. 1, the reader / writer 1 includes a generation unit 2, an amplifier 3, a carrier wave control unit 4, an antenna 5, an envelope detection unit 6, a converter 7, and capacitors C1 and C2. . The generation unit 2 generates and outputs a carrier signal having a specified frequency. The converter 7 can be an operational amplifier or a comparator. The amplifier 3 can be a transistor, an inverter, an operational amplifier, or the like.

  The amplifier 3 amplifies the carrier signal from the generation unit 2 and outputs it. The carrier control unit 4 controls on / off of the amplifier 3. The carrier wave control unit 4 modulates the carrier wave signal output from the amplifier 3 by controlling the amplification factor of the amplifier 3 according to data input from the outside.

  The antenna 5 is used for both transmission and reception, and transmits the carrier signal output from the amplifier 3 and receives the subcarrier signal transmitted from the tag.

  The envelope detector 6 receives the carrier signal amplified by the amplifier 3 and the subcarrier signal received by the antenna 5 as a received signal, and outputs an analog signal corresponding to the envelope of the received signal.

  The carrier signal output from the amplifier 3 and the subcarrier signal received by the antenna 5 are input to the envelope detection unit 6 via the capacitor C1. The envelope detector 6 is composed of, for example, a voltage doubler circuit, inputs a carrier signal and a subcarrier signal as a received signal, extracts an envelope of the received signal, and outputs an analog signal corresponding to the envelope. .

  The high-frequency component of the analog signal corresponding to the envelope output from the envelope detector 6 (signal corresponding to the rise and fall of the envelope) is input to the converter 7 through the capacitor C2. A signal corresponding to the rise and fall of the envelope and a DC offset voltage vf (reference voltage) due to voltage division are input to the pair of input terminals of the converter 7. A voltage signal is output from the output terminal of the converter 7 as a digital signal corresponding to the envelope when the analog signal is equal to or higher than the DC offset voltage vf.

  Here, in the reader / writer 1, at the start of data communication between the reader / writer 1 and the tag, the carrier wave control unit 4 switches the amplifier 3 from off to on, and outputs an unmodulated carrier signal from the amplifier 3, This unmodulated carrier wave signal is transmitted from the antenna 5. This carrier wave signal (radio wave) is received by the antenna of the tag, the tag is precharged by the power of the carrier wave signal, and the tag becomes operable.

  Thereafter, in the reader / writer 1, the carrier wave control unit 4 modulates the carrier wave signal output from the amplifier 3 by controlling the amplification factor of the amplifier 3 in accordance with data input from the outside. This modulated carrier wave signal is transmitted from the antenna 5 to the tag TG. In the tag TG, this carrier wave signal (radio wave) is received by an antenna and demodulated, and a digital signal indicating data is generated.

  In the reader / writer 1, the carrier wave control unit 4 causes the amplifier 3 to output an unmodulated carrier wave signal during a period in which data from the tag TG is received. This unmodulated carrier wave signal is transmitted from the antenna 5 to the tag TG. In the tag TG, a subcarrier signal modulated according to data to be transmitted to the reader / writer 1 is generated by reflection of a carrier wave signal (radio wave) at the antenna on the tag TG side, load control of the antenna, and the like. This subcarrier signal is transmitted.

  In the reader / writer 1, the unmodulated carrier signal output from the amplifier 3 and the subcarrier signal from the tag TG modulated by the tag TG and received by the antenna 5 are input to the envelope detector 6 via the capacitor C 1. Is done.

  The envelope detector 6 receives these carrier signals and subcarrier signals as received signals, extracts the envelope of the received signals, and outputs an analog signal corresponding to the envelope. At this time, since the carrier signal output from the amplifier 3 is unmodulated and the subcarrier signal from the tag TG received by the antenna 5 is modulated, the envelope is the subcarrier signal received by the antenna 5. It corresponds to the level change. Then, a high-frequency component of the analog signal corresponding to the envelope, that is, a signal corresponding to the rising and falling of the envelope of the subcarrier signal is applied to the converter 7 through the capacitor C2. As a result, a digital signal obtained by digitally converting the subcarrier signal from the tag TG is output from the output terminal of the converter 7.

  By the way, when the amplifier 3 is switched from amplification off to amplification on and the output of the carrier wave signal from the amplifier 3 is started, the output of the amplifier 3 rises rapidly, so that the envelope detector 6 outputs the output of the amplifier 3. An inrush current corresponding to the rising edge is generated, and a greatly increased voltage is output. This voltage is applied to the converter 7 through the capacitor C2. If the rising width of the output of the amplifier 3 is large, the voltage may exceed the rated voltage of the converter 7.

  For example, when the carrier signal is generated, if the amplification factor of the amplifier 3 is increased in order to increase the level of the carrier signal, the rising width of the output of the amplifier 3 when the amplifier 3 is switched from amplification off to amplification on becomes large. Thus, an inrush current is generated, and the voltage at this time exceeds the rated voltage of the converter 7.

  Therefore, in the reader / writer 1 of the present embodiment, the carrier wave control unit 4 switches the amplifier 3 from amplification off to amplification on and increases the amplification factor of the amplifier 3 in two stages. Specifically, assuming that a carrier wave signal h0 of a certain level is output from the generator 2 as shown in FIG. 2, the carrier wave controller 4 switches the amplifier 3 from amplification off to amplification on at time t1. At this time t1, the amplification factor of the amplifier 3 is set to α1 (an example of the second amplification factor), and the carrier signal h1 is output from the amplifier 3. Subsequently, the carrier wave control unit 4 sets the amplification factor of the amplifier 3 to a predetermined α2 (an example of the predetermined amplification factor) at a time point t2 after a predetermined time has elapsed from the time point t1. ) To output the carrier wave signal h2 from the amplifier 3.

  The prescribed amplification factor α2 is a predetermined amplification factor of the amplifier 3 that makes it possible to increase the communication distance between the reader / writer 1 and the tag. Further, the time point t2 at which the carrier wave signal h2 is output is set to a period until the tag precharge is completed. As a result, data communication with the tag can be started without any trouble.

  Here, the amplification factor α1 is smaller than the prescribed amplification factor α2, and the level of the carrier signal h1 is lower than the level of the carrier signal h2. For this reason, the voltage v1 that rises due to the inrush current that is applied to the converter 7 when the carrier wave signal h1 rises at time t1 is kept low. Further, the rising width of the carrier wave signal h2 at the time point t2 corresponds to the difference between the level of the carrier wave signal h1 and the level of the carrier wave signal h2. Also, the voltage v2 rising due to the inrush current applied to the converter 7 can be kept low. Further, since the voltage v1 decreases from the time point t1 to the time point t2, even if the voltage v2 is superimposed on the decreased voltage v1 at the time point t2, the superimposed voltage exceeds the rated voltage vd of the converter 7. There is nothing.

  Therefore, even if the carrier wave control unit 4 sets the amplification factor such that the communication distance between the reader / writer 1 and the tag is long as the prescribed amplification factor α2 of the amplifier 3, the carrier signal level is increased. The voltage that rises due to the inrush current does not exceed the rated voltage vd of the converter 7, and the durability of the converter 7 is not deteriorated or broken.

  On the other hand, as shown in FIG. 3, the amplifier 3 is switched from OFF to ON at the time t1, and the amplification factor of the amplifier 3 is set to the prescribed amplification factor α2, so that the communication distance between the reader / writer 1 and the tag is sufficient. Is immediately output from the amplifier 3, the rising width of the carrier signal h2 at the time t1 becomes large, and the voltage v3 rising due to the inrush current becomes the rated voltage of the converter 7. It will exceed vd. According to the present embodiment, such a situation can be avoided.

  In this embodiment, the amplification factor of the amplifier 3 is increased in two stages, but it may be increased in a plurality of stages of three or more stages.

  Moreover, the structure and process demonstrated using FIG. 1 thru | or FIG. 3 are only one Embodiment of this invention, and are not the meaning which limits this invention to the said structure and process.

1 Reader / Writer 2 Generation Unit 3 Amplifier 4 Carrier Control Unit 5 Antenna 6 Envelope Detection Unit 7 Converter TG Tag

Claims (3)

A generator for generating a carrier wave signal;
An amplifier for amplifying the carrier wave signal generated by the generation unit;
A control unit for controlling amplification on / off and amplification factor by the amplifier;
An antenna for transmitting a carrier signal amplified by the amplifier and receiving a subcarrier signal;
A detection unit that inputs a carrier signal amplified by the amplifier and a subcarrier signal received by the antenna as a reception signal, and outputs an analog signal corresponding to an envelope of the reception signal;
A converter for inputting an analog signal from the detection unit and outputting a digital signal corresponding to the analog signal;
The controller is configured to increase the amplification factor in a plurality of stages to increase the amplification factor of the amplifier to a predetermined prescribed amplification factor when the amplifier is switched from amplification off to amplification on. Writer.   When the control unit increases the amplification factor in a plurality of stages, the control unit sets the amplification factor as a predetermined second amplification factor lower than the prescribed amplification factor, and after a predetermined time has elapsed, The reader / writer according to claim 1, wherein the reader / writer is increased in amplification factor. The reader / writer performs data communication with a tag that receives a carrier wave signal transmitted from the antenna,
The tag precharges the power of the carrier signal before starting the data communication,
The control unit increases the amplification factor of the amplifier to a predetermined amplification factor in a plurality of stages during a period from when the amplifier is switched from amplification off to amplification on until the precharge of the tag ends. Alternatively, the reader / writer according to claim 2.