JPS6125270A - Registering system of control code for collation - Google Patents

Abstract

PURPOSE:To improve the safety of the titled registering system by changing the permission secret code for registration at every registration. CONSTITUTION:When a control code is supplied from a ten-key operation part, the code is supplied to the 1st coincidence circuit 18 of a coincidence circuit 17 via a serial/parallel converter 9. At the same time, a mode collation circuit 15 discriminates the registration mode. The data converted into a parallel form by the converter 9 are written to an ID memory circuit 11a. While a random number generating circuit 22 writes random numbers to a random number memory circuit 11b. At the same time, these random numbers are displayed at a display part of an operation display device via the converter 9. These numbers are used as the secret codes for the next registration.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a management code registration system for verification, and in particular for registering identification codes for electric locks or security devices, that is, management codes for verification of operators, for registration of electric locks or alarm devices. The present invention relates to a verification management code registration system in which registration settings and setting changes, that is, re-registration settings, can be performed easily at an installation site, and a registration permission code is changed for each registration.

BACKGROUND OF THE INVENTION Conventionally, a well-known ROM has been used as a registration means for operator verification management codes of electric lock devices or alarm devices.

This is because if a ROM is used, the registered management code will not be erased even if the power is cut off. In addition, 110M is used because it is easier to manage the security system equipped with an electric lock or alarm device by making it impossible to change the initially registered management code. On the other hand, if the operator loses the verification card, not only will the card be reissued, but
Considering the security aspect of preventing someone else from abusing the lost card, the card must be replaced with a new ROM that has a verification management code registered that is different from the previous one, and a new card that is compatible with the ROM. However, it is troublesome and has the disadvantage that it cannot be reused and must be disposed of, which increases security costs.

SUMMARY OF THE INVENTION Accordingly, the present invention solves the above-mentioned conventional drawbacks, and allows registration and re-registration of verification management codes to be easily performed at the site where the electric lock or alarm device is installed. For verification purposes, it is possible to provide a highly secure electric lock device or security system in which registration settings or re-registration settings cannot be performed, and the code for registration mode writing permission is changed each time. The aim is to provide a management code registration system.

Solution: In other words, the present invention provides a method that is input from a data input means when registering and changing a verification management code for determining whether or not an operator is a person who has been confined.
A matching circuit that compares the registration permission data at the time of registration setting of the management code with either the encryption code data or the card data based on the card operation in the data input section, and a matching signal transmitted to the matching circuit. It is equipped with a code registration means for registering card data as a management code, and a code creation means for creating an encryption code as registration permission data for the next registration setting, and an encryption code for registration permission at the time of registration operation. is made to be different each time. First, the present invention will be explained in detail based on the embodiments shown in FIGS. 1 to 4.

Embodiment Based on FIG. 1, the structure of an electric lock device will be explained as an embodiment of the present invention. This electric lock device is composed of an operation display A and a controller C1 electric lock. The operation display device A incorporates a data input device B having a card league section 1, a numeric keypad operation section 2, and a display section 3 as an integral structure, but these may be separate units. The operation display A is such that when a card of a predetermined standard is operated on the card league section 1, management data written on the card, such as a code using magnetism or optics, is read by the card league section 1. The serial data thus obtained is parallel-converted by a serial-to-parallel converter 4 made up of logic elements, and the parallel data is input to the CPtJ 5.

The CPU 5 organizes the input data into a predetermined format suitable for transmission, and then the parallel-to-serial converter 6 converts the data into serial data again, and the line driver/receiver circuit 7 outputs the data to the controller C. On the other hand, when the numeric keypad is pressed on the numeric keypad operation section 2, the parallel input data is sent from the 15 numeric keypad operation section 2 to the CPU 5, and the CPII 5 receives the input data in the same way as data input from the card described above. The parallel data is arranged into a predetermined format suitable for transmission, and the parallel data is converted into serial data by the parallel/serial converter 6, and then output to the controller C by the line driver/receiver circuit 7. Further, data sent from the controller C is received by a buffer provided in the line driver receiver circuit 7, and the serial data is converted into parallel data by the parallel/serial converter 6 and output to the CPU 5. CP[I
In step 5, the data is converted into a formant that can be displayed on the display section 3 and sent to the display section 3. The display unit 3 is composed of, for example, a liquid crystal, a fluorescent display tube, a light emitting diode, or a printer.

Next, the controller will be explained. Data sent from the operation display A, that is, numeric keypad manual data or card input data, is received by the buffer of the line driver receiver circuit 8, and converted from serial data to parallel data by a serial/parallel converter 9 composed of logic elements. Convert to cpu
Input the data into io.

The CPU 10 performs predetermined operations to be described later.
6. The drive circuit 13 writes data in the RAM 11 in accordance with the data and sends a locking/unlocking signal for the electric lock to the drive circuit 13. The drive circuit 13 is constituted by, for example, a relay circuit, and supplies a predetermined current to the electric lock, which is connected to the inside of the electric lock (not shown). Drives the actuator solenoid. Incidentally, a battery for a memory back amplifier is connected to 17AM 11 as shown in the figure.

This controller C is provided with a setting section 14 having, for example, a dip-type switch for setting an identification code for the numeric keypad. Further, when configuring a plurality of electric lock devices, the address setting of the controller C may be performed using a dip type switch of the setting section 14. CK is an oscillator such as a clock for the CPU 5.

Next, the detailed structure and operation of the controller C of the electric lock device according to the present invention will be explained based on the embodiment shown in FIG. 2. First, the operation for registering and setting the management code of this electric lock device will be explained. All management codes in this electric lock device are codes recorded on the card. However, since the encryption code used to determine whether the code on the card can be registered as a management code is changed each time the registration settings are made, confidentiality is enhanced and safety accuracy is improved. In this embodiment, the initial identification code when installing an electric lock device is a management number (a number code prepared in advance during the device manufacturing process) given to the electric lock device in advance, and is composed of, for example, a 4-digit number. has been done. At the time of leaving the warehouse, a card with this management number written on it is prepared, and a management sheet with the same management number written on it is attached to the leaving device. , ) is compared with the card, and they match -'. For registration settings from the second time onwards, when the management code is registered one time before, the cryptographic code that will be the key for the next identification code, such as a random number, is stored and displayed, and at the time of registration, the random number and number stored last time are stored and displayed.
and the data input manually from the numeric keypad operation section 2 (Fig. 1). To explain in detail, when an electric lock device is first installed, the management code, which is the identification code of this electric lock device, is not yet registered. Then, the authorized user inputs, for example, r###12 from the numeric keypad operation section 2 (Fig. 1).
Enter 34J and 7 digit data. Here, r###J is for setting the registration mode, and rl
234J is the management code model (the user knows the above management number from the attached management form).

When the above-mentioned data r###1234J is input, it is sent into the controller C, and sent to the mode matching circuit 15 by the serial/parallel converter 9. The mode verification circuit 15 detects the upper three digits from the storage circuit 12 composed of ROM, and r##
If it is #J, it is determined that it is the registration mode, and the subsequent code rl 23 is sent to the number determination circuit 16, which is composed of an adder, etc.
4J is sent and it is determined that it is the first registration,
“The data”, i.e. rl 234J, is the first
- sent to the number circuit 18; At the same time, a registration signal indicating that this is the first registration setting is sent to the buffer relay circuit 20. When the mode verification circuit 15 determines that the mode is the registration mode, a registration signal is sent to the timer 31 and the timer 31 is driven. As a result, a timer drive signal is sent to the buffer relay circuit 20. The timer 31 is connected to the numeric keypad operation section 2.
It monitors the time from (Fig. 1) to card operation, and is set to, for example, 20 seconds. Niecy is
Therefore, the card is operated in the card league section 1 (FIG. 1) within 20 seconds after the above operation. The data on the card includes, for example, a management code, an individual code, and a group code. The data read by the card league unit 1 is sent to the controller C, and the data parallel-converted by the serial/parallel converter 9 is sent to the 1g1 circuit 20 in the buffer. In the buffer relay circuit 20, when there is a timer drive signal, the data is sent as it is to the ID code writing circuit 21, and when both the timer drive signal and the registration signal are manually input by ANDing, the data is sent to the buffer relay circuit. 20 to the first-number circuit 18.

If the timer drive signal is not input to the buffer relay circuit 20, the data is sent to the verification circuit 23. Now, the first
- The number circuit 18 contains the management code data entered through the numeric keypad operation section 2 (FIG. 1), and is checked against the data on the card. The code to be checked is only rl 234J of the management code,
If they match, the first-number circuit 18 transfers the ID code writing circuit 2 to the ID code writing circuit 2.
Sends a start signal to 1. If they do not match, the controller may stop operating at that point or may display an abnormality in response to the mismatch. ID code writing circuit 21
As mentioned above, the data on the card is sent by the card operation after the numeric keypad operation, and in response to this activation signal, the data on the card is written to the ID storage circuit 11a constituted by the RAM. . At this time, since the management number on the card matches the number on the management form, rl2.34J is registered and set as the management code. At the same time, a start signal is sent to the random number generation circuit 22, so that the random number generation circuit 22 writes a random number into the random number storage circuit 11b, and at the same time writes the random number to the display section 3 of the repeat display A ( Display random numbers in Figure 1). At this time, if the display section is a printer, the random numbers are printed out. This random number will be used as the code for the next registration, so be sure to store it by writing it on the management form.

As a countermeasure in case you forget the random number code or lose the management form, you can enter a predetermined code, such as r##OJ, using the numeric keypad operation section 2 after being recognized as an approver, and the mode of the controller will be checked. The circuit 15 detects the verification mode and directly activates the random number storage circuit 11b.
The data stored in step b is displayed on the display section 3 of the operation display A via the serial/parallel converter 9. In addition, as a countermeasure against forgetting the random number digits, in the above embodiment, the numeric keypad operation section 2
However, instead of this, random numbers may be displayed by operating a separately prepared card.

Next, if the licensee currently owns a lock operation card that is lost, a new card will be issued and steps must be taken to completely invalidate the lost card, so the management code must be replaced. The stored contents of the ID storage circuit 11a are changed. To do this, enter the previously displayed random number into the registration mode "###2345J (r234jJ is a random number display) on the numeric keypad operation section 2 (FIG. 1).The mode matching circuit 15 inputs r# ##J determines that it is in the registration mode and sends r2345J to the number of times judgment circuit 16. At the same time, it sends a start signal to the timer 31, and the timer 31 operates the buffer relay circuit for a predetermined interval of 20 seconds from this point. 20. The number of times determination circuit 16 recognizes that this is the second registration setting operation, and sends the encryption code data, that is, r2345J, to the second - number circuit 19 of the - number circuit 17, and also stores the random number. A start signal is sent to the circuit 11b', and the random number generated at the previous registration stored in the random number storage circuit 11b, that is, the code r2345J, is output to the second number circuit 19. It is determined whether or not the data entered by the unit 2 and the random number match, and if they match, an activation signal is sent to the ID code writing circuit 21.

The acceptor operator operates the new card in the card league unit 1 (FIG. 1), and the data on the card (this data is not necessarily r2345J) is input to the buffer relay circuit 20. Ru. The buffer relay circuit 20 outputs the data from the card league section 1 to the ID code writing circuit 21 if the signal from the timer 21 is input. In the ID code writing circuit 21, since the activation signal is inputted as described above, the ID code writing circuit 2
1 and writes the data into the ID storage circuit 11a. At the same time, the random number generation circuit 22 is activated, and the next random number, that is, the code is manually entered into the random number storage circuit 11b, and the operation display A
The random number is displayed on the display section 3.

Next, in the electric lock device, when the user performs a normal card operation, the card is confirmed to be the specified one, and the management code recorded on the card matches the code registered in the ID storage circuit 11a of the controller C. If the electric lock is to be locked or unlocked, a drive signal for locking or unlocking the electric lock, that is, a signal for activating the actuator solenoid inside the electric lock, is output, and the electric lock is locked or unlocked.

Now, when the lock is unlocked, when a regular card is operated, the data on the card is sent from the operation display A to the controller C. The data is serial-parallel converted and sent to the buffer relay circuit 20 as described above. At this time, the buffer relay circuit 20mo outputs the data to the verification circuit 23 since the signal from the timer 21 is not input manually. At that time, the verification circuit 23
Now, the management code stored in the ID storage circuit 11a is read out and a comparison check is performed. If there is a match after this verification, the signal synthesis circuit 24, signal control circuit 25, and lock/unlock signal generation circuit 26 are used to drive a drive circuit 27 composed of a relay, for example, to unlock the electric lock. .

Here, the signal synthesis circuit 24 is used for signal synthesis when locking and unlocking is performed by ANDing the card input and the human power of the numeric keypad, or for signal control when locking and unlocking is performed using only the human power of the numeric keypad, which will be described later. The circuit 25 is used to send locking and unlocking signals by one person.

The signal control circuit 25 is also used when remotely controlling locking or unlocking using a remote controller (not shown) or when prohibiting locking or unlocking for a fixed period of 9 minutes using a timer (not shown). be done.

The numeric keypad ID setting section 14 sets the numeric keypad ID using, for example, a dip type switch, and the ID verification circuit 2
Send 10 for numeric keypad to 8.

Now, when performing locking and unlocking operations using the numeric keypad manually, input r***3456J (here, "3456" is the number set with the dip type switch in the setting section 14). When input as described above, the mode verification circuit 15 of the controller C determines the ID verification mode, and the data, that is, r3456'J, is output to the ID verification circuit 28.

If the comparison is OK, an activation signal is output to the signal synthesis circuit 24.

In the above embodiment, data transmission to a remote location was not described, but for example, when a random number is generated by the random number generation circuit 22, the numerical data of the random number may be registered in a remote location, such as a management center. Also, if there is no match in the matching operation in the matching circuit 15.23 or in the match determination in the matching circuit 17, an abnormality display may be sent to the display section 3 of the operation display A, or the control center You can also output to

Next, another embodiment of the electric lock device of the present invention shown in FIG. 3, particularly the structure and operation of the controller C, will be described.

The difference between this embodiment and the embodiment shown in FIG. 2 above is as follows.
As long as the operator of this device is confirmed to be a predetermined approver at the time of operation, the operator can create the encryption for permission to register the management data as appropriate. Further, at that time, the code can be created by combining the random numbers generated by the random number generation circuit 22 and the data input by the acceptor. In the embodiment shown in FIG. 3, circuit elements designated by the same numbers as those in the embodiment shown in FIG. 2 indicate the same circuit elements. Now, a case will be explained in which the acceptor creates an encryption code for registration permission. The operator who has become ill enters r##*4567J from the numeric keypad operation section 2. At this time, the mode verification circuit 15 determines from the storage contents of the storage circuit 12 that "##*" is a pre-stored encryption code creation mode, and sends a start signal to the second timer 32 and sends the data r4
567J is sent to the encryption registration puff circuit 29. A drive signal is sent from the second bearer 32 to the verification circuit 23 for 30 seconds, during which time the card is operated in the reader section 1 by the operating number. The data on the card read by the card reader section 1 is transferred to the buffer relay circuit 2.
0, the verification circuit 23 verifies the contents of the ID storage circuit 11a, and if the card fails, the card is determined to have been operated by the acceptor, and a match signal is sent to the cryptographic registration bar sofa circuit 29. The cryptographic registration bar sofa circuit 2 is sent.
9, upon receiving the coincidence signal, inputs and registers the previously input data, that is, r456''TJ, into the random number storage circuit 11b.The random number storage circuit Ilb sends the registered data content r4567J to the operation display A. The information is displayed on the display section 3 (FIG. 1).

After 30 seconds have passed since the second timer 32 was activated, all matching signals from the matching circuit 23 are output to the signal combining circuit 24 side. .

Next, a case will be described in which a code for registration permission is synthesized using both the random number generation circuit 22 and the operator's input data. The operator manually inputs "#**##12J" using the numeric keypad. The input data is converted by the serial/parallel converter 9 and then sent to the mode matching circuit 15. The data "#**" is read by comparing it with the stored contents, and it is determined from this data that the mode is cryptographic synthesis mode. After the determination, the mode matching circuit 15 sends the remaining data r##1, 2 to the cryptographic synthesis circuit 30 and sends a start signal to the second timer 32.
Output to. It also outputs an activation signal to the random number generation circuit 22. The second timer 32 checks the verification circuit 2 for 30 seconds.
Sends a start signal to 3. During this time, when the operator operates the card in the card league section 1, the data on the card is read. The read data on the card is sent to the verification circuit 23 via the knob relay circuit 2'0, and the verification circuit 23 determines whether it matches the content from the ID storage circuit 11a. If they match, the operator is recognized as an acceptable person and a match signal is sent to the cryptographic synthesis circuit 30. At this time, the random number generation circuit 22 has already been activated as described above, and generates a random number of a specified number of digits (4 digits) to the cryptographic synthesis circuit 30.
Send to. Therefore, in the cryptographic synthesis circuit 30, the above-mentioned four-digit random number sent from the random number generation circuit 22, for example -
When "1234" is received, it is combined with r##12J input from the numeric keypad operation section 2, and "34" is omitted and r
l Create a cipher for 212J. Once the cipher has been synthesized, this cipher i.e. r1212. J is the random number storage circuit 11b
and is registered and stored as a registration permission encryption code. At the same time as the registration and storage, the code is sent to the display section 3 (FIG. 1) of the operation display A and displayed. If the car 1 operation is not performed within 30 seconds after the numeric keypad input is performed in the above process, the verification circuit 23 will not receive the activation signal from the second timer 32, so from then on, the matching signal will not be received. is sent to the signal synthesis circuit 24.

In other words, the synthetic encryption code is not registered and stored.

In this way, the acceptor can create the encryption code for registration permission, so in this embodiment, the number of times determination circuit is used to determine the first and subsequent registration settings. If the person who approves creates the number, a circuit for determining the number of times is not necessarily required.

In this case, the approver may be determined by ID verification using a numeric keypad.

- Next, an alarm device E included in a security system as another embodiment of the present invention will be described based on FIG. 4.

To explain the alarm device E, the alarm device E activates a sensor 47 that detects when an abnormality such as an intrusion, a fire outbreak, or a gas leak occurs in the warning area. A security mode button 41 for setting the mode,
Based on the detection signal and the security mode, it is determined whether the detection signal is abnormal or not, and when the determination result is abnormal, it is connected to a remote management center 48 to which an abnormality signal is sent. First, the fourth
The registration setting of the management code as the pre-acceptance verification ID will be explained according to the figure. This management code is all code recorded on the card. However, since the encryption code for determining whether the code on this card can be registered as a management code is changed each time it is registered, it is highly confidential and the accuracy of security is improved. First, when the operator inputs, for example, "***5678" using the numeric keypad operation section 2 of the data input device B provided in the alarm device, it is sent to the mode verification circuit 15, and the mode verification circuit 15 stores it in the ROM. The configured memory circuit detects the upper three digits, and if "**+kJ", it determines that it is ID verification mode, and determines whether the operator is an authorized person or not.
78J is sent to the ID verification circuit 28. The operator sets the acceptor number as "5678" in advance using the ID setting section 14, which is comprised of a dipstick. Therefore, the ID verification circuit 28 inputs the set number r5678J sent from the ID setting section 14, and starts the second timer 32 when it determines that the operator is an authorized person.

If these numbers do not match, an abnormality may be displayed.

This second timer 32 sends a start signal to the cipher generation circuit for, for example, 30 seconds. Next, when the operator inputs "##*6789J" using the numeric keypad operation section 2, the mode verification circuit 1
In step 5, if it is "##*", it is determined that the mode is the encryption code creation mode, r6789J is output to the encryption creation circuit 30, and this r6789J is stored in the encryption storage circuit 11'b.

If it is determined to be this encryption code creation code, the random number generation circuit 22 may be activated and the random number may be used as the registration permission encryption code. Next, the operator presses r###6789J on the numeric keypad operation section 2.
When input by
If it is J, it is determined that it is the registration mode, the first timer 31 is activated, and r6789J is sent to the coincidence circuit 17.

The matching circuit 17 inputs the code already stored in the code storage circuit 11111, that is, r6789J, and determines whether or not there is a match. When the match circuit 17 confirms the match, it outputs a registration permission signal to the ID code writing circuit 21. The first timer 31 outputs a start signal to the buffer relay circuit 20 for, for example, 20 seconds. A card given to an acceptor in advance is read by a cart reader part 1. The buffer relay circuit 20 sends the read verification ■D code, ie, the management code, and sends this management code to the ID code writing circuit 21 when receiving the activation signal. When the activation signal is not received, the management code read by the buffer relay circuit 20 is output to the verification circuit 23.

The ID code writing circuit 21 stores the management code in the ID storage circuit 11a. From now on, unless the management mode is re-registered, this management code will become the permitter verification ID. At this time, the random number generation circuit 22 is activated to create a cipher for the next registration permission, send it to the cipher storage circuit llb, and output the cipher to the display section 3 to notify the operator of the cipher for the next registration permission. . When the operator wants to set the security mode, he operates the card in the cart reader section 1. The management code on the card is sent to the verification circuit 23 via the buffer relay circuit 20, and the verification circuit 23 reads the code stored in the ID storage circuit 11a and determines whether the operator is an authorized person. It is checked and determined whether or not. If the person is recognized as an acceptable person, a mode change permission signal is sent to the security mode setting circuit 42 for a predetermined period of time. The operator then presses the security mode button 41, for example, the "night mode" button. When the night mode button is pressed, a one-shot multi-vibration break MM3 is sent to the security mode setting circuit 42 for 5 seconds and stored in the security mode storage circuit 43. At this time, when the sensor 47 detects an intruder, the sensor turns on or off, and due to this turning on or off, the abnormality detection circuit t6 detects that the sensor has detected the intruder, and sends a detection signal to the abnormality determination circuit 44. .

In the abnormality determination circuit 44, in the security mode storage circuit 43, "
A message indicating that the mode is "Night Farm" mode is sent to the abnormality determination circuit 44,
Determine it as abnormal. This intrusion abnormality signal is sent to a remote management center via the sending circuit 45. Further, at this time, the abnormality may be displayed on the display section 3. Next time when you register for the second time, the encryption code for registration permission is already 1.
Since it is displayed in the first registration, all you have to do is input "### encrypted code" from the numeric keypad operation section 2 based on the encrypted code. The subsequent operations are the same as described above. In this embodiment, the security mode was set using the security mode button 41, but the security mode could be changed uniformly (for example, alternately from ``at home'' to 4 to ``nighttime''), and the user could be identified as an authorized person simply by operating the card. The mode may be changed when this happens. In this embodiment, the random number generation circuit 22 is used, but instead of this, the random number generation circuit 22 is used. The cipher numbers may be created based on some kind of equation (random number generation circuit - cipher creation circuit) [Example] Year Months Days Hours - Addition Addition Readout 5+9)X
3=42→4+2=6 (0+6)x3=18→l+8=9 (1+0)x3=3□→3 (0+9)X3=27□→9 This is how the coded number r9396J is obtained.

The security level is improved because the registration permission code for registering the effect of the invention is different each time it is registered.

When registering, only authorized operators can register, so the degree of security is high.

Numeric keypad operations and card operations are both easy user registration operations.

Since the management code can be registered and set at the site of the electric lock or alarm device, the complicated management process of matching the card and controller at the time of shipping or installing the electric lock or alarm device can be reduced, and ultimately Cost reduction can be achieved.

- It is possible to re-register the management code, so if you lose your card, you can simply replace it.

Since the management code is stored as data on the card, if the data is recorded using a magnetic recording method, the written contents cannot be read by others. In other words, the management code cannot be read by anyone other than the authorized person, making it safer. You can hope to improve your degree. □

[Brief Description of the Drawings] Fig. 1 is a block diagram showing the basic configuration of the electric lock device according to the present invention, Fig. 2 is a circuit configuration diagram showing an embodiment of the lock/unlock controller of the same device, and Fig. 3 is the same. FIG. 4 is a circuit diagram of another embodiment of the controller, and FIG. 4 is a circuit diagram of an embodiment of the alarm device according to the present invention. A-operation display, B-data input device, C.-controller, D-electric lock, E-alarm device, 11a-) ID storage circuit, llb.-random number storage circuit, 12-memory circuit 15-. Mode verification circuit, 16--number of times determination circuit, 17'--11-1 matching circuit, 20--buffer relay circuit, 22-- random number generation circuit, 23-- matching circuit.

Claims (1)

[Claims] 1. When registering and changing the verification management code for determining whether the operator is an authorized person,
a matching circuit that compares registration permission data at the time of registration setting of the management code input from the data input means with data of either the encryption code data or the card data based on the card operation in the data input means; It is equipped with a code registration means for registering card data as a management code based on a matching signal from a circuit, and a code creation means for creating an encryption code as registration permission data for the next registration setting. A management code registration system for verification, characterized in that the encryption code for the verification is different each time. 2. The verification management code registration system according to claim 1, wherein the data input means includes a display section that displays the code created by the code creation means. 3. The verification management code according to claim 1, wherein the code registration means is activated by a registration setting operation and includes a built-in time limit means for monitoring the time until the next card operation. Registration system. 4. The verification management code registration system as set forth in claim 1, wherein the cryptographic creation means is a random number generation circuit. 5. The verification management code registration system according to claim 1, wherein the cryptographic creation means includes a cryptographic synthesis circuit that synthesizes data input by the data input means. 6. The verification management code registration system according to claim 1, wherein the code creation means registers data input by a data input means. 7. Claim 6, characterized in that the cryptographic creation means is driven when a verification circuit that verifies data input from the data input means and a predetermined ID sends out a matching signal. The verification management code registration system according to any one of Section 7. 8. The matching circuit as set forth in claim 1, wherein the matching circuit has a equality discriminating circuit for discriminating the number of registration setting operations of the management code inputted from the data input means at the preceding stage. Code registration system.