JP3953913B2 - IC card reader - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to, for example, an IC card reader (IC card reader / writer) that performs data communication (data processing) with a contact-type or non-contact-type IC card incorporating a storage element.
[Prior art]
In recent years, there are IC cards that use different operating power sources, such as 1.8V, 3V, and 5V operating voltage values, and other IC cards have multiple operating power supply voltage values. Some IC cards can selectively use them (see Patent Document 1), and a plurality of types of IC cards having different operation power sources coexist.
[0002]
As an IC card reader that accepts various types of IC cards in this coexistence state, it is necessary to provide a plurality of different power supply voltages and switch them according to the operating power of the IC card so that data communication with these various types of IC cards is possible. (See Patent Document 2).
[0003]
In order to determine the operating power of the various IC cards described above, a predetermined voltage is supplied to determine whether activation is possible. If activation is not possible, and if the reception level is not a predetermined value, Although the same determination is performed by supplying the power of the voltage value, conventionally, the switching order of such voltages has not been considered, so that the above determination takes time and the processing performance is degraded. There is a problem of doing.
[0004]
In other words, the usage status of the various IC cards described above varies depending on the region and the user organization, and when determining the voltage of the operating power supply, it takes much time if it is determined from the types of cards used. In addition, if an IC card with a low operating power supply voltage value is suddenly activated at a high voltage and data communication is performed, there is a risk of destroying the card IC or data.
[0005]
[Patent Document 1]
JP-A-9-330387 [Patent Document 2]
Japanese Patent Laid-Open No. 10-370901.
[0006]
[Problems to be solved by the invention]
An object of the present invention is to provide an IC card reader capable of shortening the time required for activation and preventing destruction of the IC card based on activation when receiving and activating various IC cards having different power supply voltages. And
[0007]
[Means for Solving the Problems]
The present invention provides an IC card reader for data communication after supplying and activating power to the IC card when the IC card is received, and a plurality of power supply voltages set for activating the IC card The IC card reader is characterized in that a plurality of activation modes having different supply orders are set and the activation modes can be selected.
[0008]
As an embodiment, the activation mode includes an ascending order mode in which the power source is switched from the smaller value side of the set power source voltage to the larger value side.
Further, the activation mode includes a descending order mode in which the power source is switched from the larger value side of the set power source voltage to the smaller value side.
Furthermore, the activation mode includes a frequency order mode in which the power source is switched from a value side with a high frequency of use of the power source voltage to a value side with a low frequency.
Further, the activation mode includes a fixed mode in which the power supply voltage is fixed to a predetermined value.
Furthermore, in the activation mode, an ascending order mode in which the power source is switched from a small value side of the set power supply voltage to a large value side, a descending order mode in which the power source is switched from a large value side of the set power supply voltage to a small value side, use of the power supply voltage At least two modes are included: a frequency order mode in which the power source is switched from a high value side to a low value side, and a fixed mode in which the power source voltage is fixed to a predetermined value.
[0009]
[Operation and effect of the invention]
According to the present invention, since a plurality of activation modes having different power supply voltage supply orders set in order to activate the IC card can be selected, this activation mode can be selected from various IC cards, for example. By selecting according to the usage environment, the time required for activation can be shortened, and destruction of the IC card based on activation can be prevented.
[0010]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described with reference to the drawings.
The drawing shows an IC card reader capable of reading and writing data by performing data communication with an IC card. In FIG. 1, the IC card reader 10 includes a CPU 11, a flash memory 12, and a RAM 13. The CPU 11 is a flash memory. The activation of the IC card and data processing are executed in accordance with the program stored in 12, and the RAM 13 stores data necessary for the operation.
[0011]
The interface circuit 14 connects the CPU 11 and the IC card 15, the oscillator 16 generates clock pulses to be applied to the IC card 15, and the power supply circuit 17 generates a plurality of voltage values of power to be supplied to the IC card. In this example, voltage values of 1.8 V, 3 V, and 5 V are disclosed, but the voltage values are not limited to these values.
[0012]
In addition, when the power supply voltage used by the IC card is, for example, a low-voltage power supply and the frequency of the clock pulse changes accordingly, the basic clock pulse is divided to correspond to the clock frequency of the IC card. You can also.
[0013]
When the above-mentioned IC card 15 is a contact type IC card by contact contact, it is connected so as to be communicable by contact of an IC contact, and when it is a non-contact type IC card by radio wave connection, it is communicably connected using an antenna. Is done.
[0014]
The above-described CPU 11 is communicably connected to a host 18 that is a host device, and executes data processing on the IC card 15 according to a command from the host 18.
[0015]
The signal line connecting the CPU 11 and the interface circuit 14 includes a voltage designation signal (Voltage) a1 for designating the operating power supply voltage of the IC card, a power supply voltage (Vcc) control signal a2 for ON / OFF control of the power supply, and a supply. These are signal lines of a clock (CLK) control signal a3 for controlling output / non-output of a clock to be output, a reset signal (RST) a4 for initialization, and a data signal (I / O) a5 to be input / output.
[0016]
The signal line connecting the interface circuit 14 and the IC card 15 is input / output with a power supply voltage (Vcc) b2 for operating, a clock signal (CLK) b3, a reset signal (RST) b4 for initialization. Each signal line of the data signal (I / O) b5.
[0017]
The IC card reader 10 shown in this embodiment shows an example of processing three types of IC cards in which the operating power supply voltage of the IC card 15 is 1.8V, 3V, and 5V. The frequency of the clock pulse in these three types of IC cards 15 is the same frequency.
[0018]
When these various IC cards 15 are activated, a plurality of activation modes are set in which the supply sequence of the operating power supply voltage corresponding to each IC card 15 is different.
That is, when any type of IC card 15 is inserted into a card insertion slot formed in the IC card reader 10, for example, the operating power of the IC card 15 is 1.8V, 3V, or 5V. It is necessary to determine whether.
[0019]
In this determination, each operation power supply voltage is supplied to determine readability and reception level, and the operation power supply sequence is set to a plurality of modes.
[0020]
The first mode is 5V → 3V → 1.8V (descending order mode)
The second mode is 5V → 1.8V → 3V
The third mode is 3V → 5V → 1.8V
The fourth mode is 3V → 1.8V → 5V
The fifth mode is 1.8V → 3V → 5V (ascending order mode)
The sixth mode is 1.8V → 5V → 3V
7th mode is fixed at 5V (voltage setting mode)
8th mode is fixed at 3V (voltage setting mode)
9th mode is fixed at 1.8V (voltage setting mode)
The first mode described above is a descending order mode in which the power source is switched from the larger value side of the set power supply voltage to the smaller value side,
The above-mentioned fifth mode is an ascending order mode in which the power supply is switched from the small value side to the large value side of the set power supply voltage,
The second, third, fourth, and sixth modes are modes in which the power source is switched from the higher value side of the power supply voltage to the lower value side, and the mode suitable for the frequency of use is selected and used in the frequency order mode. To do. Even in the first and fifth modes, if the usage frequencies match, these are also applied as the frequency order mode. The seventh, eighth, and ninth modes are used as voltage setting modes when the operating power supply is a single IC card.
[0021]
Then, the processing programs from the first mode to the ninth mode are stored in the flash memory 12.
[0022]
Which of the activation modes described above is used by the IC card reader 10 is selected based on statistics, and the activation mode specified and used from the host 18 side is set. The processing program for the activation mode described above may be stored on the host 18 side, and when the activation mode is selected on the host 18 side, the processing program for the selected activation mode may be downloaded.
[0023]
The operation of the activation process of the IC card reader 10 configured as described above will be described with reference to the flowchart of FIG.
[0024]
For example, when an automatic deposit payment machine is installed at an unattended corner of a financial institution and it is assumed that many financial institutions will use it together, each financial institution will have a unique IC card with a unique power supply voltage set. The automatic deposit payment machine described above handles a plurality of IC cards having different power supply voltage values. Considering these usage statistics by handling a large number of IC cards at the same time, various usage situations are judged by the surrounding environment of the unmanned corner, and when many IC cards with a power supply voltage of 5V are used, this When activation is first performed with a power supply voltage of 5 V, activation is completed with high probability. Also, when activation cannot be performed with this, assuming that the power supply voltage value that is most often used next, for example, 3 V, activation is completed with the next highest probability by activation with the power supply voltage. it can.
[0025]
In this way, the activation mode is selected and activated according to the usage status of the IC card 15. The selection determination of the activation mode described above is performed on the host 18 side, and the determined activation mode is transmitted to the CPU 11 of the IC card reader 10.
[0026]
The CPU 11 reads the activation mode transmitted from the host 18 (step n1), selects the corresponding activation mode from the first to ninth modes stored in the flash memory 12, and executes its processing program. Read (step n2).
[0027]
If the selected activation mode is the ascending order mode (the fifth mode described above), the activation process is executed in the ascending order mode described later (steps n3 and n4), and the descending order mode (the first mode described above). ), The activation process is executed in the descending order mode described later (steps n5, n6). If the frequency order mode (for example, the second, third, fourth, and sixth modes), the frequency order mode described later is executed. (Steps n7 and n8), and in the set voltage mode, the activation process is executed with the set voltage, for example, 5V, 3V, or 1.8V (see FIG. Steps n9 and n10).
[0028]
In the set voltage mode, since the power supply voltage of the card used is known in advance, the activation is completed with the set power supply voltage.
[0029]
FIG. 3 shows the activation process in the ascending order mode in step n4 described with reference to FIG. 2, and this ascending order mode supplies the operating power supply voltage in the ascending order of 1.8V → 3V → 5V in the fifth mode described above. In this mode, readability is determined.
[0030]
The CPU 11 supplies the IC card 15 with a power supply designating 1.8V of the power supply circuit 17 and a clock signal and a reset signal to execute activation (step n21).
[0031]
When the power is supplied, the IC card 15 sends back an ATR signal (Answer To Reset). Therefore, the CPU 11 determines whether or not the ATR signal can be read. It is checked whether it is supported and whether there is information on the operating power supply voltage as appendix information.
[0032]
That is, if the ATR signal cannot be read, it is determined that the operating power supply voltage is different (steps n22 and n23).
[0033]
In addition, even if the above ATR signal can be received, if the communication parameters are not supported, for example, if the communication protocol is different, it is determined that the IC card 15 is not allowed to trade and the processing is completed as activation failure. (Step n24).
[0034]
Further, when the read level of the received ATR signal is at a level at which it can be determined that the operating power supply voltage matches, or the operating power supply voltage information (voltage value) is recorded as appendix information in the ATR signal, and the recorded voltage If the value information matches the supplied power supply voltage value, the process is terminated as activation completion (step n25).
[0035]
However, if the voltage value of the appendix information exists but the voltage value does not match the voltage value supplied for activation, the supply voltage for activation is set to the voltage value of the appendix information, Activation is completed (steps n26 and n27).
[0036]
Further, when the information (voltage value) of the operating power supply voltage is not recorded as appendix information in the ATR signal, and when the read level of the ATR signal is not at a level where it can be determined that the operating power supply voltage matches, When it is determined in step n23 that the ATR signal cannot be read, the activation process is stopped (step n28), and then it is determined whether there is a supply voltage in the ascending order mode. If it has been completed and there is no voltage to be supplied next, it is determined that the IC card 15 is not allowed to be dealt with, and the process is completed as an activation failure (step n29).
[0037]
However, if there is a power supply voltage to be supplied next in the ascending order mode, the power supply voltage is set to the voltage value, activation is performed (step n30), and the process returns to step n22.
[0038]
As described above, in the ascending order mode (the fifth mode described above), the value of the operating power supply voltage to be supplied is activated by supplying it in ascending order of 1.8 V → 3 V → 5 V in this embodiment, If it is not activated, it is determined that the IC card 15 is not allowed to trade, and the process is completed as activation failure.
[0039]
FIG. 4 shows the activation process in the descending order mode at step n6 described with reference to FIG. 2. This ascending order mode supplies the operation power supply voltage in the descending order of 5V → 3V → 1.8V in the first mode described above. In this mode, readability is determined.
[0040]
The CPU 11 supplies the IC card 15 with a power supply specifying 5V of the power supply circuit 17 and a clock signal and a reset signal to execute activation (step n31).
[0041]
When the power is supplied, the IC card 15 returns an ATR signal. Therefore, the CPU 11 determines whether or not the ATR signal can be read. If it is read, whether or not the communication parameter is supported. Further, it is checked whether or not there is information on the operating power supply voltage as appendix information.
[0042]
That is, when the ATR signal cannot be read, it is determined that the operating power supply voltage is different (steps n32 and n33).
[0043]
Even if the above ATR signal can be received, if the communication parameter is not supported, it is determined that the IC card 15 does not permit the transaction, and the process is completed as an activation failure (step n34).
[0044]
Further, when the read level of the received ATR signal is at a level at which it can be determined that the operating power supply voltage matches, or the operating power supply voltage information (voltage value) is recorded as appendix information in the ATR signal, and the recorded voltage If the value information matches the supplied power supply voltage value, the process is terminated as activation completion (step n35).
[0045]
However, if the voltage value of the appendix information exists but the voltage value does not match the voltage value supplied for activation, the supply voltage for activation is set to the voltage value of the appendix information, Activation is completed (steps n36 and n37).
[0046]
In addition, when the information (voltage value) of the operating power supply voltage is not recorded as appendix information in the ATR signal, and when the read level of the ATR signal exceeds a level at which it can be determined that the operating power supply voltage matches, When it is determined in step n33 that the ATR signal cannot be read, the activation process is stopped (step n38), and then it is determined whether there is a supply voltage in the descending order mode. If no voltage is supplied next, it is determined that the IC card 15 is not allowed to be dealt with, and the processing is completed as activation failure (step n39).
[0047]
However, if there is a power supply voltage to be supplied next in the descending order mode, the power supply voltage is set to the voltage value, activation is performed (step n40), and the process returns to step n32.
[0048]
Thus, in the descending order mode (the first mode described above), the value of the operating power supply voltage to be supplied is activated by supplying from a large value to a small value, in this embodiment, in descending order of 5V → 3V → 1.8V, If it is not activated, it is determined that the IC card 15 is not allowed to trade, and the process is completed as activation failure.
[0049]
FIG. 5 shows the activation process of the frequency order mode in step n8 described with reference to FIG. 2, and this frequency order mode is [highest frequency voltage value] → [next frequency voltage value] → [lowest frequency]. In this mode, the operation power supply voltage is supplied in the order of frequency such as [Voltage value] and the readability is determined. The order of the frequencies is set in advance by taking card usage (utilization) statistics.
[0050]
The CPU 11 supplies the IC card 15 with a power supply having a voltage value corresponding to the highest frequency designated by the power supply circuit 17 and performs activation (step n41).
[0051]
When the power is supplied, the IC card 15 returns an ATR signal. Therefore, the CPU 11 determines whether or not the ATR signal can be read. If it is read, whether or not the communication parameter is supported. Further, it is checked whether or not there is information on the operating power supply voltage as appendix information.
[0052]
That is, when the ATR signal cannot be read, it is determined that the operating power supply voltage is different (steps n42 and n43).
[0053]
Even if the ATR signal can be received, if the communication parameter is not supported, it is determined that the IC card 15 does not permit the transaction, and the process is completed as an activation failure (step n44).
[0054]
Further, when the read level of the received ATR signal is at a level at which it can be determined that the operating power supply voltage matches, or the operating power supply voltage information (voltage value) is recorded as appendix information in the ATR signal, and the recorded voltage If the value information matches the supplied power supply voltage value (step n45), the use frequency of the power supply voltage value is incremented by 1 (step n48), and the process is terminated as the activation is completed.
[0055]
However, if the voltage value of the appendix information exists but the voltage value does not match the voltage value supplied for activation, the supply voltage for activation is set to the voltage value of the appendix information (step n47) Further, +1 is added to the frequency of use of the power supply voltage value (step n48), and the process is terminated as the activation is completed.
[0056]
Further, when the information (voltage value) of the operating power supply voltage is not recorded as appendix information in the ATR signal, and when the read level of the ATR signal is not at a level where it can be determined that the operating power supply voltage matches, or exceeds When it is determined in step n43 that the ATR signal cannot be read, the activation process is stopped (step n49), and then it is determined whether there is a supply voltage of the next frequency in the frequency order mode. If supply at the lowest frequency has already been completed and there is no voltage to be supplied next, it is determined that the IC card 15 is not allowed to be dealt with, and the process is completed as activation failure (step n50).
[0057]
However, if there is a power supply voltage of the next frequency as the frequency order mode, the power supply voltage is set to the voltage value, activation is performed (step n51), and the process returns to step n42.
[0058]
As described above, in the frequency order mode, the value of the operating power supply voltage to be supplied is activated by setting the value of the use (use) frequency from the high value side to the low value side, and when it is not activated, the transaction is allowed. It is determined that the card is not the IC card 15 and the processing is completed as activation failure.
[0059]
As described above, according to this embodiment, a plurality of activation modes having different power supply voltage supply orders set in order to activate the IC card 15 are selected, that is, an ascending order mode, a descending order mode, and a frequency order mode. Therefore, by selecting this activation mode according to the usage environment of various IC cards 15, for example, the time required for activation can be shortened, and destruction of the IC card based on activation can be prevented. can do.
[0060]
In the above-described embodiment, the operation power supply voltage of the IC card 15 has been described as three types of 1.8V, 3V, and 5V for convenience of explanation. However, four types including two of these or other types are included. The present invention can also be applied to the above operating power supply voltage, and the present invention is not limited to the configuration of the embodiment, including other configurations, and has many embodiments.
[Brief description of the drawings]
FIG. 1 is a block diagram of an IC card reader.
FIG. 2 is a flowchart of activation processing.
FIG. 3 is a flowchart of activation processing in an ascending order mode.
FIG. 4 is a flowchart of activation processing in an ascending order mode.
FIG. 5 is a flowchart of activation processing in an ascending order mode.
[Explanation of symbols]
10 ... IC card reader 11 ... CPU
15 ... IC card 17 ... power supply circuit

Claims (6)

An IC card reader for data communication after receiving an IC card, supplying power to the IC card and activating the IC card,
An IC card reader in which a plurality of activation modes having different power supply voltage supply orders set in order to activate the IC card are set, and the activation mode can be selected. 2. The IC card reader according to claim 1, wherein the activation mode includes an ascending order mode in which the power source is switched from a small value side to a large value side of the set power supply voltage. 2. The IC card reader according to claim 1, wherein the activation mode includes a descending order mode in which the power source is switched from a larger value side of a set power supply voltage to a smaller value side. 2. The IC card reader according to claim 1, wherein the activation mode includes a frequency order mode in which the power source is switched from a higher value side to a lower value side. The IC card reader according to claim 1, wherein the activation mode includes a fixed mode in which a power supply voltage is fixed to a predetermined value. In the activation mode,
Ascending mode to switch the power supply from the small value side to the large value side of the set power supply voltage,
A descending order mode that switches the power supply from the larger value side of the set power supply voltage to the smaller value side,
Frequency order mode that switches the power supply from the high value side to the low value side,
2. The IC card reader according to claim 1, comprising at least two modes among fixed modes in which the power supply voltage is fixed to a predetermined value.

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