JP3935002B2 - Non-contact type IC card reader / writer device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a non-contact type IC card reader / writer device that reads / writes data from / to a non-contact IC card.
[0002]
[Prior art]
This kind of non-contact type IC card reader / writer device has an antenna and is electromagnetically coupled to the antenna of the non-contact IC card via this antenna to supply power to the non-contact IC card and transfer data to the non-contact IC card. Read / write is performed. Such non-contact IC cards have been upgraded from IC cards having only a memory to IC cards having a memory and a CPU, and more recently to IC cards having a built-in coprocessor for encryption processing. Functionalization is progressing.
[0003]
The power consumption of such an IC card increases with higher functionality, while the non-contact type IC card reader / writer device that supplies power to the IC card also needs to increase the transmission output as the power consumption of the IC card increases. Conventionally, the non-contact type IC card reader / writer device can stably operate on the IC card side in consideration of the load conditions on the IC card side such as the number of IC cards with different power consumption or the number of IC cards to which power is supplied. Transmission output is performed under the maximum load condition.
[0004]
[Problems to be solved by the invention]
The conventional non-contact type IC card reader / writer device has a problem that the power consumption of the device increases because the transmission output is set under the maximum load condition in which the IC card side can stably operate.
Therefore, an object of the present invention is to reduce power consumption of a non-contact type IC card reader / writer device.
[0005]
[Means for Solving the Problems]
  In order to solve such a problem, the present invention provides a modulation circuit that shifts the amplitude voltage of a carrier in accordance with the value of a binary signal of input data and outputs it as an amplitude-shifted modulation signal. When the output amplitude shift keying signal is input, it is transmitted as a radio signal to a non-contact type IC card, and has a non-contact type antenna unit that supplies power to the non-contact type IC card and transmits the data. The IC card reader / writer device has a power supply circuit that generates a predetermined power supply voltage, and also has a plurality of constant current circuits that each output a constant current of a constant value, and outputs a constant current from the selected constant current circuit. A power supply unit that supplies the modulation circuit together with a predetermined power supply voltage of the power supply circuit; and a selection unit that selects at least one of the plurality of constant current circuits of the power supply unit.IsThe constant current circuit is selected according to whether or not the non-contact type IC card responds to the transmission of the radio signal from the antenna unit. If there is no response from the non-contact type IC card, the number of constant current circuits to be selected is selected. While the number is increased by one, the number of constant current circuits to be selected is decreased by one when there is a response from the non-contact type IC card.
[0006]
  The modulation circuit includes a carrier generation unit that generates a carrier, a modulation unit that shifts the amplitude voltage of the carrier from the carrier generation unit according to the value of the binary signal of the input data, and a signal from the modulation unit. It consists of a driver that sends it to the antenna section as an amplitude shift signal, and supplies a constant current from the constant current circuit of the power supply section to the driver..
  MaThe modulation circuit outputs an amplitude shift modulation signal at a predetermined period when a response from the non-contact type IC card is not detected with respect to the transmission of the radio signal, and the selection means outputs the amplitude shift modulation signal of the modulation circuit. One constant current is output when an amplitude shift modulation signal is output in the next period of the modulation circuit after all constant current circuits are selected at the time of modulation signal output and a constant current from the selected constant current circuit is supplied to the modulation circuit. By selecting a circuit, a constant current from the selected constant current circuit is supplied to the modulation circuit.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
The present invention will be described below with reference to the drawings.
FIG. 3 is a block diagram showing the configuration of the non-contact type IC card reader / writer device according to the present invention.
In FIG. 3, a non-contact type IC card reader / writer device (hereinafter referred to as an IC card reader / writer) 1 includes a control unit 11 that controls the entire IC card reader / writer 1, a modulation circuit 12, a matching circuit 13, and a resonance circuit. The circuit 14, the demodulation circuit 15, and a power supply unit 16 that supplies power to each of the above units are configured.
[0008]
Here, the modulation circuit 12 modulates a carrier generated from a carrier generation unit, which will be described later, according to the value of the data signal SD output from the control unit 11 and outputs the modulated signal to the matching circuit 13.
The matching circuit 13 receives the output signal from the modulation circuit 12 and outputs the output signal to the resonance circuit 14. The matching circuit 13 can also transmit the output signal from the resonance circuit 14 to the IC card described later efficiently. Impedance matching is achieved.
[0009]
The resonance circuit 14 has an antenna coil L1 that is an induction element and a capacitive element C connected in parallel. When a modulation signal is given from the modulation circuit 12 via the matching circuit 13, the resonance circuit 14 starts resonance and generates a radio signal from the antenna coil L1. It is generated and transmitted to the IC card electromagnetically coupled to the antenna coil L1.
When the demodulating circuit 15 inputs a modulation signal via the resonance circuit 14 returned from the IC card in response to the transmission of the radio wave signal, the demodulating circuit 15 demodulates the modulation signal, extracts data, and outputs it to the control unit 11 as received data RD. To do.
[0010]
The control unit 11 in the IC card reader / writer 1 is connected to a host device (not shown) and performs data communication with the host device, thereby recording received data from the host device on the IC card and data read from the IC card. Is transmitted to the host device.
The power supply unit 16 in the IC card reader / writer 1 includes a first power supply circuit that generates a power supply voltage 5VA and a second power supply circuit that generates a power supply voltage 5VB when an external power supply PW is input. The power supply voltage 5VA of the circuit is output to the control unit 11 and the demodulation circuit 15, and the power supply voltage 5VB of the second power supply circuit is output to the modulation circuit 12.
[0011]
FIG. 4 is a block diagram showing a configuration of the IC card that is electromagnetically coupled to the IC card reader / writer 1.
4, the IC card 2 includes an antenna coil L2, a wireless interface 21, a control circuit 22 such as a CPU, and a memory 23 in which an ID and information unique to the IC card are stored.
[0012]
When the antenna coil L1 of the IC card reader / writer 1 and the antenna coil L2 of the IC card 2 are electromagnetically coupled, the wireless interface 21 of the IC card 2 generates and controls the power POWER by the radio wave signal from the IC card reader / writer 1. In addition to being supplied to the circuit 22 and the memory 23, a clock signal CLK is generated and applied to the control circuit 22, and data DATA is extracted from the radio signal and output to the control circuit 22.
When the power POWER from the wireless interface 21 is supplied, the control circuit 22 of the IC card 2 reads data DATA from the wireless interface 21 in synchronization with the clock signal CLK, and this data DATA is write data to the memory 23. Is recorded in the memory 23. On the other hand, if the data DATA is command data for reading the data in the memory 23, the data in the memory 23 is read and output to the wireless interface 21.
[0013]
The operation of the IC card reader / writer 1 and the IC card 2 will be described in detail with reference to FIGS.
When the control unit 11 of the IC card reader / writer 1 receives data for the IC card from the host device, the control unit 11 outputs the data SD to the modulation circuit 12. When the data SD from the control unit 11 is input, the modulation circuit 12 amplitude-shift-modulates a carrier having a predetermined frequency generated from a carrier generation unit, which will be described later, according to the value of the input data SD, and the matching circuit 13 and the resonance circuit. 14 to transmit as a radio wave signal.
[0014]
When the radio interface 21 of the IC card 2 receives a radio signal from the IC card reader / writer 1 via the antenna coil L2, the power POWER is supplied to the control circuit 22 as described above, and the radio signal 21 is activated. Data DATA (ie, data SD) is extracted from the data and output to the activated control circuit 22.
Here, when the received data DATA from the IC card reader / writer 1 is write data to the memory 23, the control circuit 22 records this data in the memory 23. If the data DATA is command data for reading data in the memory 23, the data in the memory 23 is sequentially read in synchronization with the clock signal CLK and output to the wireless interface 21 side.
[0015]
Data sequentially read from the memory 23 of the IC card 2 is transmitted as a radio wave signal to the IC card reader / writer 1 side via the wireless interface 21 and the antenna coil L2.
When the resonance circuit 14 of the IC card reader / writer 1 receives the radio signal from the IC card 2, it outputs the radio signal to the demodulation circuit 15 as a modulation signal. The demodulation circuit 15 demodulates the modulation signal to extract data from the modulation signal, and outputs the extracted data RD of the memory 23 of the IC card 2 to the control unit 11. When the control unit 11 receives the data RD from the demodulation circuit 15, the control unit 11 transmits the data RD to the host device.
[0016]
In this way, the IC card reader / writer 1 can write data to the IC card 2 and can read data written to the IC card 2.
In FIG. 4, the IC card 2 is provided with a control circuit 22 such as a CPU, but the control circuit 22 may be omitted. Such an IC card in which the control circuit 22 is omitted has a configuration in which the power POWER and the clock CLK are directly output from the wireless interface 21 to the memory 23, and a transmission / reception data line is directly connected between the wireless interface 21 and the memory 23. In addition, the power consumption can be halved compared to the IC card 2 having the control circuit 22. For an IC card on which such a control circuit 22 is not mounted, the IC card reader / writer 1 directly accesses the memory 23 via the wireless interface 21 to write and read data.
[0017]
FIG. 2 is a block diagram showing a configuration of the modulation circuit 12 of the IC card reader / writer 1. The modulation circuit 12 includes a carrier generation unit 12A that generates a carrier a, a modulation unit 12B that performs amplitude shift modulation of the carrier a from the carrier generation unit 12A according to a binary signal of transmission data SD from the control unit 11, and The transmission driver 12 </ b> C outputs the modulation signal of the modulation unit 12 to the matching circuit 13. Here, the power supply voltage 5VA is supplied from the power supply unit 16 to the carrier generation unit 12A and the modulation unit 12B in the modulation circuit 12, and the power supply voltage 5VB is supplied from the power supply unit 16 to the transmission driver 12C.
[0018]
(First embodiment)
FIG. 1 is a block diagram showing a first embodiment of the power supply unit 16 of the IC card reader / writer 1.
As shown in FIG. 1, the power supply unit 16 includes a 5VA power supply circuit 161 that generates a power supply voltage 5VA (that is, the first power supply circuit described above) and a power supply voltage based on the power supply voltage 5VA of the 5VA power supply circuit 161. It is composed of a 5VB power supply circuit 162 (that is, the aforementioned second power supply circuit) composed of constant current circuits 163 and 164 that generate 5VB.
[0019]
Here, the constant current circuits 163 and 164 are respectively I₁ A, I₂ The constant current circuit 163 is composed of an N-channel junction field effect transistor Q1 and a resistor R1, while the constant current circuit 164 is an N circuit having the same configuration as the constant current circuit 163. A P-channel MOS field effect transistor Q3 and a resistor R3 are further added to the channel junction field effect transistor Q2 and the resistor R2.
[0020]
In the constant current circuit 163, the transistor Q1 is always turned on, and the current is constant I.₁ The transistor Q2 of the constant current circuit 164 is turned on only when the control signal CNT of "L" level is output from the control unit 11 and the transistor Q3 is turned on, and the constant value I is output.₂ A current is output.
[0021]
Therefore, the 5VB power supply circuit 162 is always I from the constant current circuit 163.₁ A current of A is output, and when the control signal CNT from the control unit 11 becomes “L” level, I from the constant current circuit 164₂ The output current of A is added and the total (I₁ + I₂ ) Output A current. That is, the 5VB power supply circuit 162 is always connected to the transmission driver 12C which is the output unit of the modulation circuit 12.₁ A current is supplied to the external IC card 2 from the transmission driver 12C.₁ A) can be output, and (I) is transmitted to the transmission driver 12C of the modulation circuit 12 in accordance with the “L” level of the control signal CNT from the control unit 11.₁ + I₂ ) A current is supplied, and the supply current ((I₁ + I₂ ) Enables output of A).
[0022]
FIG. 5 is a diagram showing a communication sequence between the IC card reader / writer 1 and the IC card 2. The operation of the first main part of the present invention according to this sequence will be described.
First, the IC card reader / writer 1 sets the control signal CNT of the control unit 11 to the “L” level, so that the current value (hereinafter referred to as current level) supplied from the power supply unit 16 to the transmission driver 12C of the modulation unit 12 is ( I₁ + I₂ ) A to send a request command to the IC card 2 (step S1). Here, when the IC card 2 does not exist within the communicable range of the IC card reader / writer 1, no response is returned from the IC card 2 to the IC card reader / writer 1. Therefore, the IC card reader / writer 1 transmits a request command to the IC card 2 again after a certain time t1 has elapsed (step S2). At this time, the control signal CNT of the control unit 11 is set to the “H” level (that is, current level = I₁ A) A request command is transmitted.
[0023]
In response to the transmission of the request command from the IC card reader / writer 1 to the IC card 2, when the response is not yet returned from the IC card 2, the IC card reader / writer 1 again checks the IC card after a certain time t1 has elapsed. A request command is transmitted to 2 (step S3). At this time, the control signal CNT of the control unit 11 is set to the “L” level state (current level = (I₁ + I₂ ) Send a request command in A).
[0024]
As described above, when the IC card 2 does not exist within the communicable range of the IC card reader / writer 1 and a response from the IC card 2 cannot be obtained, the IC card reader / writer 1 sets the control signal CNT to the “L” level state. (Current level = (I₁ + I₂ ) A) the request command and the control signal CNT are in the “H” level state (current level = I₁ The request command as A) is repeatedly transmitted alternately.
[0025]
Here, the IC card 2 is placed in the communicable range of the IC card reader / writer 1 (step S4), and at this time, the control signal CNT is set to the “H” level state (current level) from the IC card reader / writer 1 to the IC card 2. = I₁ When the request command A) is transmitted (step S5) and a request response representing a response to the request command is returned from the IC card 2 (step S6), the IC card reader / writer 1 sets the control signal CNT to “H”. Level (current level = I₁ A command for establishing communication with the IC card 2 (hereinafter referred to as a card activation command) is transmitted while maintaining in (A) (step S7).
[0026]
When a card activation command is transmitted from the IC card reader / writer 1 to the IC card 2, a card activation command response indicating a response to the card activation command is returned from the IC card 2 to the IC card reader / writer 1 (step S8), and the IC card 2 is activated (step S9).
When the IC card 2 is thus activated, the control signal CNT continues to be at the “H” level (current level = I₁ Communication with a card command is performed between the IC card reader / writer 1 and the IC card 2 in a state where A) is maintained (steps S10 and S11).
[0027]
In the above example, only one command in step S7 has been described as the card activation command. However, a plurality of card activation commands are transmitted after the request command until the IC card 2 is activated. There is no problem even if there is a case. In the above example, when the IC card 2 is not within the communicable range of the IC card reader 1, only the request command is transmitted continuously, but the request command and the card activation command are one command, You may make it transmit continuously. In this case, it goes without saying that the request command and the card activation command are transmitted at the same current level. Furthermore, the request command, the card activation command, and the card command may be set as one command and transmitted continuously. In this case, the request command, the card activation command, and the card command are naturally transmitted at the same current level.
[0028]
Next, the operation of the second main part of the present invention will be described with reference to the sequence diagram of FIG.
When the IC card 2 is not within the communicable range of the IC card reader / writer 1 and a request response cannot be obtained from the IC card 2, the IC card reader / writer 1 sets the control signal CNT to the “L” level as described above. (Current level = (I₁ + I₂ ) Set the request command A) and the control signal CNT to the “H” level (current level = I₁ The request command as A) is repeatedly transmitted alternately.
Here, the IC card 2 is placed in the communicable range of the IC card reader / writer 1 (step S4), and at this time, the control signal CNT is transferred from the IC card reader / writer 1 to the IC card 2 at the “L” level (current level = (I₁ + I₂ ) When the request command as A) is transmitted (step S21) and a request response is returned from the IC card 2 (step S22), the IC card reader / writer 1 sets the control signal CNT of the control unit 11 to the “H” level ( Current level = I₁ Switch to A) and send the request command again (step S23).
[0029]
When a request response to the request command is returned from the IC card 2 (step S24), the IC card reader / writer 1 determines that the control signal CNT is at the “H” level (current level = I₁ While maintaining A), a card activation command is transmitted to the IC card 2 (step S25).
In response to this card activation command transmission, a card activation command response is returned from the IC card 2 (step S26), and when the IC card 2 transitions to the activated state (step S27), the control signal CNT continues to “H”. Level (current level = I₁ Communication with a card command is performed between the IC card reader / writer 1 and the IC card 2 in a state where A) is maintained (steps S28 and S29). In this example as well, it goes without saying that there is no problem even if a plurality of card activation commands are transmitted after the request command and before the IC card 2 is activated.
[0030]
Next, the operation of the third main part of the present invention will be described with reference to the sequence diagram of FIG.
A request response cannot be obtained from the IC card 2 and the IC card reader / writer 1 sets the control signal CNT to the “L” level (current level = (I₁ + I₂ ) Set the request command A) and the control signal CNT to the “H” level (current level = I₁ The IC card 2 is placed within the communicable range of the IC card reader / writer 1 when the request command A) is alternately and repeatedly transmitted (step S4), and at this time, the IC card reader / writer 1 to the IC card 2 The control signal CNT is changed to “L” level (current level = (I₁ + I₂ ) When the request command as A) is transmitted (step S21) and a request response is returned from the IC card 2 (step S22), the IC card reader / writer 1 sets the control signal CNT of the control unit 11 to the “H” level. (Current level = I₁ Switch to A) and send the request command again (step S23).
[0031]
If a request response is not returned from the IC card 2 even after a predetermined time has elapsed after the transmission of this request command, the IC card reader / writer 1 determines that a timeout has occurred and sets the control signal CNT to the “L” level ( Current level = (I₁ + I₂ ) The request command as A) is transmitted to the IC card 2 (step S31).
[0032]
When a request response to the request command is returned from the IC card 2 (step S32), the IC card reader / writer 1 determines that the control signal CNT is at the “L” level (current level = (I₁ + I₂ ) A card activation command is transmitted to the IC card 2 while maintaining A) (step S33).
In response to this card activation command transmission, a card activation command response is returned from the IC card 2 (step S34), and when the IC card 2 transitions to the activation state (step S35), the control signal CNT “L” continues. ”Level (current level = (I₁ + I₂ ) Communication by the card command is performed between the IC card reader / writer 1 and the IC card 2 in a state where A) is maintained.
[0033]
As described above, in the first embodiment, when the IC card 2 does not exist within the communicable range of the IC card reader / writer 1 and a request response cannot be obtained from the IC card 2, every certain time t1. The power supply unit 16 alternately transmits the transmission driver 12C in the modulation circuit 12 (I₁ + I₂ ) A or I₁ By supplying the current of A, the transmission output current from the transmission driver 12C is (I₁ + I₂ ) A or I₁ When the request command is transmitted to A and a request response from the inserted or placed IC card 2 is detected, the transmission output current of the transmission driver 12C is I₁ In the case of A, the control unit 11 of the IC card reader / writer 1 subsequently uses the transmission output current of the transmission driver 12C in the modulation circuit 12 as I when communicating with the IC card 2.₁ A is defined as A and the command is transmitted with this transmission output current. Thereby, the power consumption of the IC card reader / writer 1 when the IC card 2 does not exist in the communicable range of the IC card reader / writer 1 can be reduced. The transmission output current I from the IC card reader / writer 1₁ When a request response is returned in response to transmission of a request command by A, an IC card with low power consumption is placed or inserted in the communicable range of the IC card reader / writer 1, or one sheet This is a case where an IC card is placed or inserted.
[0034]
On the other hand, the transmission output current of the transmission driver 12C when the request response from the IC card 2 is detected in response to the transmission of the request command is (I₁ + I₂ ) A, the control unit 11 of the IC card reader / writer 1 sets the transmission output current of the transmission driver 12C in the modulation circuit 12 to (I₁ + I₂ ) A to I₁ Reduce to A and send the request command again. If a request response from the IC card is detected at this time, the control unit 11 of the IC card reader / writer 1 similarly places a low power consumption IC card in the communicable range of the IC card reader / writer 1. It is determined that the IC card is placed or inserted, or one IC card is placed or inserted, and when communicating with this IC card thereafter, the transmission output current of the transmission driver 12C is set to I₁ The command is transmitted by setting it as A.
[0035]
The transmission output current of the transmission driver 12C in the modulation circuit 12 is expressed as (I₁ + I₂ ) A to I₁ When a request command from the IC card is not detected when the request command is transmitted to A, the control unit 11 of the IC card reader / writer 1 subsequently transmits the transmission driver 12C when communicating with the IC card 2. Output current of (I₁ + I₂ ) Send a command to A. Transmission output current (I) from such an IC card reader / writer 1₁ + I₂ ) When a request response is returned in response to the transmission of a request command by A, an IC card with high power consumption is placed or inserted in the communicable range of the IC card reader / writer 1, or a plurality of This is a case where the IC card is placed or inserted.
[0036]
In this way, the IC card reader / writer 1 can switch the transmission output current accurately in accordance with the power consumption of the mounted or inserted IC card, the number of mounted or inserted IC cards, and the like. The power consumption of the writer 1 can be controlled to an optimum state, and as a result, the power consumption of the IC card reader / writer 1 can be reduced.
Further, since only the current of the transmission driver 12C, which is the output unit of the modulation circuit 12, is controlled, the power consumption of the IC card reader / writer 1 can be limited with high accuracy.
In addition, since a constant current is supplied from the constant current circuit of the power supply unit 16 to the transmission driver 12C of the modulation circuit 12 and is output as a transmission current, foreign matter such as metal is present in the antenna coil L1 of the IC card reader / writer 1. Even when approaching, an excessive current does not flow in the IC card reader / writer 1, and the power consumption of the IC card reader / writer 1 can be suppressed to a certain value or less.
[0037]
(Second Embodiment)
FIG. 8 is a block diagram showing a second embodiment of the power supply unit 16 of the IC card reader / writer 1.
As shown in FIG. 8, the power supply unit 16 includes a 5VA power supply circuit 161 that generates a power supply voltage 5VA, and constant current circuits 163 and 164 that generate a power supply voltage 5VB based on the power supply voltage 5VA of the 5VA power supply circuit 161. 5VB power supply circuit 162 composed of 165 and 166.
[0038]
Here, the constant current circuits 163 and 164 are respectively I₁ A, I₂ The constant current circuit 163 is composed of an N-channel junction field effect transistor Q1 and a resistor R1, while the constant current circuit 164 is an N circuit having the same configuration as the constant current circuit 163. A P-channel MOS field effect transistor Q3 and a resistor R3 are further added to the channel junction field effect transistor Q2 and the resistor R2. Further, the constant current circuits 165 and 166 are respectively connected to I_Three A, I_Four A constant current circuit 165 can output a constant current of A. The constant current circuit 165 includes an N channel junction field effect transistor Q4 and a resistor R4 having the same configuration as the constant current circuit 163, and further a P channel MOS field effect transistor Q5 and a resistor R5. Is added to the N-channel junction field effect transistor Q6 and the resistor R6 having the same configuration as the constant current circuit 163, and the P-channel MOS field effect transistor Q7 and the resistor R7 are further added. It has an added configuration.
[0039]
In the constant current circuit 163, the transistor Q1 is always turned on, and the current is constant I.₁ The transistor Q2 of the constant current circuit 164 is turned on only when the "L" level control signal CNT1 is output from the control unit 11 and the transistor Q3 is turned on, and the constant value I is output.₂ A current is output. The transistor Q4 of the constant current circuit 165 is turned on only when the “L” level control signal CNT2 is output from the control unit 11 and the transistor Q5 is turned on._Three A current is output. Further, the transistor Q6 of the constant current circuit 166 is turned on only when the “L” level control signal CNT3 is output from the control unit 11 and the transistor Q7 is turned on._Four A current is output.
[0040]
Therefore, the 5VB power supply circuit 162 is always I from the constant current circuit 163.₁ A current of A is output, and when the control signal CNT1 of the control unit 11 becomes “L” level, I from the constant current circuit 164₂ The output current of A is added and the total (I₁ + I₂ ) Output A current. Further, at this time, when the control signal CNT2 of the control unit 11 becomes “L” level, I from the constant current circuit 165_Three The output current of A is added and the total (I₁ + I₂ + I_Three ) A current of A is output, and at this time, if the control signal CNT3 of the control unit 11 further becomes "L" level, I from the constant current circuit 166_Four The output current of A is added and the total (I₁ + I₂ + I_Three + I_Four ) Output A current.
[0041]
That is, the 5VB power supply circuit 162 is always connected to the transmission driver 12C, which is the output unit of the modulation circuit 12, with respect to I.₁ A current can be supplied from the transmission driver 12C, so that I can be supplied from the transmission driver 12C to the external IC card 2.₁ A current output of A is possible, and (I) is sent to the transmission driver 12C of the modulation circuit 12 in accordance with the “L” level of each control signal CNT1, CNT2, CNT3 from the control unit 11.₁ + I₂ ) A [when CNT1 = "L", CNT2,3 = "H"], or (I₁ + I₂ + I_Three ) A [when CNT1, 2 = "L", CNT3 = "H"], or (I₁ + I₂ + I_Three + I_Four ) A [when CNT1, 2, 3 = "L"] or (I₁ + I_Three ) A [when CNT2 = "L", CNT1,3 = "H"], or (I₁ + I_Four ) A [when CNT3 = "L", CNT1,2 = "H"], or (I₁ + I_Three + I_Four ) A [when CNT2, 3 = “L”, CNT1 = “H”], or (I₁ + I₂ + I_Four ) By enabling the supply of any current value of A [when CNT1, 3 = “L”, CNT2 = “H”], the supply current value is output to the external IC card 2 from the transmission driver 12C. It is what makes it possible.
[0042]
FIG. 9 is a diagram illustrating a communication sequence between the IC card reader / writer 1 having the power supply unit and the IC card 2 according to the second embodiment. The operation of the fourth main part of the present invention according to this sequence will be described.
The IC card reader / writer 1 first sets the current level to (I) by setting the control signals CNT1, CNT2 and CNT3 of the control unit 11 to the “L” level.₁ + I₂ + I_Three + I_Four ) A request command A is transmitted to the IC card 2 (step S41). Here, when the IC card 2 does not exist within the communicable range of the IC card reader / writer 1, the request response is not returned from the IC card 2 to the IC card reader / writer 1. After t1 has elapsed, the current level is set to (I₁ + I₂ + I_Three ) Switch to A and send the request command again (step S42).
[0043]
If a request response is not returned from the IC card 2 for the transmission of the request command, the IC card reader / writer 1 sets the current level to (I₁ + I₂ ) Switch to A and send the request command again (step S43). If a request response is not returned from the IC card 2 for the transmission of this request command, the IC card reader / writer 1 sets the current level to I after a certain time t1 has elapsed.₁ Switch to A and send the request command again (step S44).
[0044]
As described above, when the IC card 2 is not within the communicable range of the IC card reader / writer 1 and a request response cannot be obtained from the IC card 2, the IC card reader / writer 1 sets the current level to (I₁ + I₂ + I_Three + I_Four ) A to (I₁ + I₂ + I_Three ) To A, (I₁ + I₂ + I_Three ) A to (I₁ + I₂ ) To A, (I₁ + I₂ ) A to I₁ A request command is sent to A in order of decreasing level, and the minimum level I₁ If the request response is not returned even when the request command A is sent, the IC card reader / writer 1 again sets the current level to the minimum level I.₁ The maximum level (I₁ + I₂ + I_Three + I_Four ) Return to A and send the request command. That is, when the IC card reader 1 cannot obtain a request response from the IC card 2, the processes of steps S41 to S44 are repeatedly executed.
[0045]
Here, the IC card 2 is placed in the communicable range of the IC card reader / writer 1 (step S45), and at this time, the current level is changed from the IC card reader / writer 1 to the IC card 2 (I₁ + I₂ ) When a request command A is transmitted (step S46) and a request response is returned from the IC card 2 (step S47), the IC card reader / writer 1 sets the current level to I.₁ Switch to A and send the request command again (step S48).
[0046]
If the request response is not returned from the IC card 2 even after a predetermined time has elapsed after the transmission of this request command, the IC card reader / writer 1 determines that a time-out has occurred and sets the current level to the previous (I₁ + I₂ ) Return to A and send the request command to the IC card 2 again (step S49).
[0047]
When a request response to the request command is returned from the IC card 2 (step S50), the IC card reader / writer 1 sets the current level to (I₁ + I₂ ) A card activation command is transmitted to the IC card 2 while maintaining A (step S51).
In response to this card activation command transmission, a card activation command response is returned from the IC card 2 (step S52). When the IC card 2 transitions to the activation state (step S53), the current level continues to be (I₁ + I₂ ) Communication with a card command is performed between the IC card reader / writer 1 and the IC card 2 in a state maintained at A (steps S54 and S55).
[0048]
In the example of FIG. 9, only one command in step S51 has been described as the card activation command. However, after the request command, a plurality of card activation commands are transmitted before the IC card 2 is activated. There is no problem even if there are cases. In the example of FIG. 9, when the IC card 2 is not in the communicable range of the IC card reader / writer 1, the IC card reader / writer 1 continuously transmits only the request command. The command may be transmitted continuously as one command. In this case, it goes without saying that the request command and the card activation command are transmitted at the same current level. Furthermore, the request command, the card activation command, and the card command may be set as one command and transmitted continuously. In this case, the request command, the card activation command, and the card command are naturally transmitted at the same current level.
[0049]
In the example of FIG. 9, the current level is (I₁ + I₂ ) An example in which a request response is returned from the IC card 2 when a request command with A is transmitted has been described.₁ + I₂ + I_Three + I_Four ) If a request response is returned from the IC card 2 when a request command A is sent, the current level is set to (I₁ + I₂ + I_Three ) When the request command set to A is transmitted again and a request response to the request command is returned, the current step is set to (I₁ + I₂ ) A request command set to A is transmitted again, and the request command is transmitted by sequentially decreasing the current level by one step. When a response from the IC card 2 is not returned in response to the transmission of the request command and a time-out occurs, the request command is transmitted again after returning the current level to the next higher level, and thereafter, with the IC card 2 Switch to communication using card commands. Note that the current level is the minimum I₁ If a request response is returned from the IC card 2 when a request command is transmitted by A, the minimum current level I is thereafter received.₁ A communicates with the IC card 2. As described above, even when there are three or more current levels, communication can be performed between the IC card reader / writer 1 and the IC card 2 at the minimum current level by the same method as that when there are two current levels.
[0050]
In the example of FIG. 9, a request command is transmitted while the current level is lowered by one step, and after a request command is transmitted at the minimum current level, the request command is transmitted again after returning to the maximum current level. The example of repetition has been described. For example, when a request command is transmitted while repeating the maximum and minimum current levels, and a request response is returned from the IC card 2 in response to transmission of the request command at the maximum current level, The request command is transmitted while decreasing the level by one step to find the minimum current level communicable with the IC card 2, or the request command is transmitted while increasing the current level by one step from the minimum level. If a request response is returned, the current level is set to 1. It transmits a request command while lowering floor increments, there is a method of finding the minimum current level possible communication with the IC card 2. The object of the present invention is achieved if the minimum current level that can be communicated with the IC card 2 can be finally found by using any of these methods. Therefore, the present invention is a method for finding the minimum current level. It is not limited by.
[0051]
【The invention's effect】
As described above, according to the present invention, the amplitude voltage of the carrier is shifted according to the value of the binary signal of the input data and output as an amplitude-shifted modulation signal, and output from the modulation circuit. When an amplitude shift keying signal is input, an IC card reader / writer having an antenna unit that transmits a radio wave signal to the IC card and supplies power to the IC card and transmits the data is provided. The unit has a power supply circuit that generates a predetermined power supply voltage, and has a plurality of constant current circuits that each output a constant current of a constant value, and the constant current from the selected constant current circuit Since the modulation circuit is supplied together with the power supply voltage, the constant current circuit can be selected. Therefore, when the transmission current is output from the reader / writer side under the maximum load condition as in the past. It is possible to avoid a situation where Tsu, this result, it becomes possible to reduce the power consumption of the reader-writer device.
Moreover, since the constant current from the constant current circuit of the power supply unit is supplied to the driver of the modulation circuit, the power consumption of the reader / writer device can be limited with high accuracy.
[0052]
In addition, a selection unit that selects at least one of a plurality of constant current circuits of the power supply unit is provided, and the selection unit reduces the power consumption of the non-contact type IC card that is electromagnetically coupled to the antenna unit based on transmission of a radio signal from the antenna unit Since the constant current circuit is selected accordingly, the power consumption of the reader / writer device can be controlled to an optimum state.
Further, the selection means selects all constant current circuits at the time of output of the amplitude shift keying modulation signal of the modulation circuit and supplies the constant current to the modulation circuit, and then outputs the amplitude shift modulation signal in the next cycle of the modulation circuit. Since one constant current circuit is sometimes selected and a constant current is supplied to the modulation circuit, the power consumption of the reader / writer device when no IC card is placed or inserted in the reader / writer device can be reduced.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a first main configuration of a non-contact type IC card reader / writer device according to the present invention.
2 is a block diagram showing a configuration of a modulation circuit in the non-contact type IC card reader / writer device of FIG. 1;
3 is a block diagram showing the overall configuration of the non-contact type IC card reader / writer device of FIG. 1. FIG.
4 is a block diagram of an IC card from / to which data is read / written by the non-contact type IC card reader / writer device of FIG. 1. FIG.
FIG. 5 is a sequence diagram showing a first operation of the non-contact type IC card reader / writer device of FIG. 1;
6 is a sequence diagram showing a second operation of the non-contact type IC card reader / writer device of FIG. 1. FIG.
7 is a sequence diagram showing a third operation of the non-contact type IC card reader / writer device of FIG. 1. FIG.
FIG. 8 is a block diagram showing a second main configuration of the non-contact type IC card reader / writer device.
9 is a sequence diagram showing an operation of a main part of the non-contact type IC card reader / writer device of FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Non-contact IC card reader / writer, 2 ... IC card, 11 ... Control part, 12 ... Modulation circuit, 12A ... Carrier generation part, 12B ... Modulation part, 12C ... Transmission driver, 13 ... Matching circuit, 14 ... Resonance circuit, DESCRIPTION OF SYMBOLS 15 ... Demodulation circuit, 16 ... Power supply part, 21 ... Wireless interface, 22 ... Control circuit, 23 ... Memory, 161 ... 5VA power supply circuit, 162 ... 5VB power supply circuit, 163-166 ... Constant current circuit, Q1, Q2, Q4 Q6: N-channel junction field effect transistor, Q3, Q5, Q7: P-channel MOS field effect transistor, R1 to R7: Resistance, C: Capacitance element, L1, L2: Antenna coil.

Claims (3)

A modulation circuit that shifts the amplitude voltage of the carrier in accordance with the value of the binary signal of the input data and outputs it as an amplitude shift modulation signal, and an amplitude shift modulation signal output from the modulation circuit is input without contact In a non-contact type IC card reader / writer device having an antenna unit that transmits an electric wave signal to a type IC card and supplies power to the non-contact type IC card and transmits the data,
A power supply circuit that generates a predetermined power supply voltage, and a plurality of constant current circuits each outputting a constant current of a constant value, and the constant current from the selected constant current circuit is supplied to the predetermined power supply of the power supply circuit A power supply for supplying the modulation circuit together with a voltage;
Selecting means for selecting at least one of a plurality of constant current circuits of the power supply unit, wherein the selecting unit is determined according to the presence or absence of a response of the non-contact type IC card to the transmission of the radio signal from the antenna unit. When a current circuit is selected and there is no response from the non-contact type IC card, the number of constant current circuits to be selected is increased by one, while when there is a response from the non-contact type IC card A non-contact type IC card reader / writer device, wherein the number of constant current circuits to be selected is reduced by one. In claim 1 ,
The modulation circuit includes a carrier generation unit that generates a carrier, a modulation unit that shifts the amplitude voltage of the carrier from the carrier generation unit according to the value of the binary signal of the input data, and the amplitude of the signal from the modulation unit It consists of a driver that sends it to the antenna as a deviation signal,
A non-contact type IC card reader / writer device, wherein a constant current from a constant current circuit of the power supply unit is supplied to the driver. In claim 1 ,
The modulation circuit outputs the amplitude shift modulation signal at a predetermined cycle when a response from the contactless IC card is not detected with respect to the transmission of the radio signal,
The selection means selects all the constant current circuits at the time of output of the amplitude shift modulation signal from the modulation circuit, supplies a constant current from the selected constant current circuit to the modulation circuit, and then selects the next to the modulation circuit. A non-contact type IC card reader / writer device, wherein one constant current circuit is selected and a constant current from the selected constant current circuit is supplied to the modulation circuit when the amplitude shift keying signal is output in a period of .

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