KR920003342B1 - A cordless telephone with secret numbers - Google Patents

Abstract

The code is set by communicating between a handset and a base unit. The method comprises steps: (A) checking the contact state of a handset and a base unit; (B) storing the counter value on a memory as a code, sending the code to the handset through a contact (30); (B) receiving and storing the code onthe handset; (C) transmitting the code stored on the handset to the base unit through the contact; (D) compring the transmitted code and received code by the base unit and storing the code when two codes are coincide; and (E) setting the stored code as a new code when new code is not transmitted from the handset after a fixed time.

Description

How to specify password for cordless phone

1 is a conventional password designation circuit and flow chart.

2 is a system block diagram for carrying out the present invention.

3 is a schematic diagram of contact between a handset and a base.

4 is a flowchart of operation of the base unit according to the present invention.

5 is a flowchart of operation of a handset unit according to the present invention.

* Explanation of symbols for main parts of the drawings

11, 21: Micom 12, 22: RF control unit

13, 23: antenna 14, 24: audio control unit

15: telephone line interface 25: keyboard

30: contact part

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a password designation method of a wireless telephone, and more particularly, to a method for specifying a password by performing data communication only to a base unit and a handset unit of a wireless telephone.

In general, a radiotelephone separates a base unit and a handset unit to perform wireless communication between the handset unit and the base unit, and performs a wired communication for the base unit and the exchange period.

At this time, if the wireless telephone meets only the wireless communication distance between the base unit and the handset unit, the call can be made even if the handset is changed. If the user carries only the handset, he can easily steal through any base, which may cause problems in billing and the like. In order to prevent this, a password is used in a wireless telephone. In the related art, a password is designated using a switch SW1-SWn as shown in FIG. The password designation reads the state of the switches SW1-SWn connected to the microcomputer 1 as shown in FIG. 1B, and then designates the data. However, the above method has a high risk of theft because it is easy to adjust the password, and since the number of switches is determined according to the number of switches, the password is restricted and the switch is set to specify a password. As a result, many I / O ports are used, which makes it difficult to use microcomputers efficiently and has a problem of cost increase.

It is therefore an object of the present invention to provide a method for specifying a password by performing data communication between a base unit and a handset unit in a radiotelephone.

It is still another object of the present invention to transmit a random count value to the handset unit whenever the base unit contacts the handset unit, and retransmit the count value received by the handset unit to the base unit. By comparing the transmitted and received count values, if the same count value is specified as a password, the received count value can be specified as a password if the handset unit does not receive another count value until a certain time has elapsed. Is in.

Hereinafter, the present invention will be described in detail with reference to the drawings.

2 is a block diagram of a radiotelephone for carrying out the present invention, showing the configuration of the base unit 10 and the handset unit 20. As shown in FIG.

First, referring to the configuration of the base unit 10, the first microcomputer 11 performs a function of controlling the overall operation of the base unit 10. The telephone line interface unit 15 performs an interfacing function with the base unit 10 during the exchange period under the control of the first microcomputer 11. The first RF controller 12 performs a wireless communication function with the handset unit 20 under the control of the first microcomputer 11. The first audio controller 14 processes the audio signal to perform a call function through the speaker phone under the control of the first microcomputer 11.

Second, referring to the configuration of the handset unit 20, the second microcomputer 21 performs a function that can control the overall operation of the handset unit 20. The keyboard 25 is connected to the second microcomputer 21 and generates key data for setting a dial function and a call function. The second RF controller 22 performs a wireless communication function with the bear unit 10 under the control of the second microcomputer 21. The second audio controller 24 processes the audio signal to perform a call function through the handset under the control of the second controller 21.

When the base unit 10 and the handset unit 20 are in contact with each other, the contact unit 30 forms a supply passage for operating power and designates a password as a random count value counted by the first microcomputer 11. Form a data path.

3 is a configuration diagram of the contact portion 30, wherein the CB1-CB3 terminals are terminals of the base unit 10, and the CH1-CH3 terminals are terminals of the handset unit 20. As shown in FIG. When the base unit 10 and the handset unit 20 are in contact with each other, the CB1 terminal and the CH1 terminal are terminals for supplying a first power source Vcc which is an operating power source, and the CB2 terminal and the CH2 terminal are the first microcomputer 11 and A communication terminal for transmitting and receiving serial data between the second microcomputer 21, and the CB3 terminal and the CH3 terminal is a terminal for supplying a second power source that is a ground power source. At this time, since the power of the handset unit 20 uses the power supplied from the base unit 10, the battery BAT is used, and the battery BAT is connected to the CH1 terminal through a diode D to connect the handset unit ( When 20) contacts the base unit 10, it receives and charges the first power source Vcc of the CH1 terminal applied through the CB1 terminal. Therefore, even if the handset unit 20 and the base unit 10 are spaced apart, the handset unit 20 can perform a wireless communication function by the battery BAT power supply.

4 is an operation flowchart of the base unit 10, and reads the value of the internal counter that is counting at random when contacted with the handset unit 20, and transmits it as a password, and compares the received password with the transmitted password. If it is the same, set the corresponding count value as a password. If the two numbers are different, the process is repeated by reading the value of the internal counter again. In addition, when confirming contact release during the transmission or reception of the password, the operation of specifying the password is stopped and the previous password is maintained.

5 is a flowchart of the operation of the handset unit 20. When the contact is detected with the base unit 10, the receiver enters a reception state, receives a password, and retransmits the received password. After that, if a new password is not received until a certain time elapses, the received and stored password is stored as a new password, and when the new password is received, the above process is repeated. In addition, if a contact release is recognized during the reception or transmission of the password, the operation of specifying the password is stopped and the previous password is maintained as it is. The password specifying operation is performed every time the base unit 10 and the handset unit 20 come into contact.

Based on the above-described configuration, the present invention will be described in detail with reference to FIGS.

First, the call function of the wireless telephone, the telephone line interface unit 15 performs a function for performing wired communication through the telephone line. In addition, wireless communication is performed between the base unit 10 and the handset unit 20. First, in the base unit 10, a voice signal received through the telephone line interface unit 15 receives the RF signal through the first RF control unit 12. The signal is modulated and output to the handset unit 20 through the antenna 13. In the handset unit 20, the RF signal received through the antenna 23 is demodulated into a voice signal through the second RF controller 22 and reproduced as a voice signal through the second audio controller 24. In addition, the key data or voice signal generated through the keyboard 25 or the second audio control unit 24 of the handset unit 20 is modulated into an RF signal through the second RF control unit 22 and then the antenna 23 is operated. It is output to the base unit 10 through. The output signal is then demodulated by the first RF control unit 12 of the base unit 10 and output to the exchange via the telephone line interface unit 15. Here, the first microcomputer 11 controls the overall operation of the base unit 10, and the second microcomputer 21 controls the operation of the handset unit 20. In addition, the first audio control unit 14 controls the voice signal to perform a call of the speaker phone function.

The contact portion 30 connecting the first microcomputer 11 and the second microcomputer 21 of the radiotelephone as described above is configured as shown in FIG. 3, when the handset unit 20 is placed on the base unit 10. The first power supply terminals CB1 and CH1, the second power supply terminals CB3 and CH3 and the communication terminals CB2 and CH2 are contacted. Here, CB1, CH1, CB3, and CH3 terminals are terminals for charging the battery BAT built in the handset unit 20, and CB2 and CH2 are passwords between the base unit 10 and the handset unit 20. It is a communication terminal to designate. That is, when the base unit 10 and the handset unit 20 come into contact with each other, CB1, CH1, CH3, and CH3 are connected to each other, and the power supply Vcc of the base unit (! 0) is charged to the battery BAT, and the CB2 And CH2 are in contact with each other, the supply power supply (Vcc) supplies high-level power to the P _H port of the first microcomputer 21 through CB1, CH1 and the resistor R2 so that the second microcomputer 21 contacts. The second microcomputer 11 also detects a contact state because the voltage passing through the CB2 and CH2 is applied to the P _B port.

Since the base unit 10 when outputting a count value at the contact point P through the _B port via an internal counter, for receiving a count value from the handset unit 20 it is done to specify a password. In this case, the counter for specifying a password may use a counter inside the microcomputers 11 and 21, and may also occur by using a separate counter outside the microcomputers 11 and 21. In the present invention, a counter inside the microcomputers 11 and 21 is used. That is, the first microcomputer 11 and the second microcomputer 21 are processors (single chip microprocessor) incorporating a memory (ROM, RAM) and an internal timer, and the internal counter configuration of the first microcomputer 11 is as follows. It has the same configuration as

The counter is used for password designation and uses a timer interrupt inside to increase the counter value by one for each timer interrupt period. If the counter is a 16-bit counter and the timer interrupt period is 300 μsec, the initial value of the counter becomes ＂0000 _H ,, and the counting value is incremented by 1 in 300 μsec period, and is initialized again when＂ FFFF _H ＂. The count operation resumes from "0000 _H ". Therefore, the counter increases in count value every timer interrupt period regardless of whether the handset unit 20 and the base unit 10 are in contact, and the first microcomputer 11 reads the counter value at the point of contact and the password is read. Perform the operation to specify. In this case, the number of passwords is 2 ₁₆ = 65,536.

Referring to the above-described operation of specifying the password with reference to the flow charts of FIGS. 4 and 5, the first microcomputer 11 and the second microcomputer 21 perform steps 401 and 501, respectively, to contact each other. Check for presence That is, the first microcomputer 11 and the second microcomputer 21 examine the states of the P _B port and the P _A port, respectively, and consider the contact state if the port state is the logic high state, and the logic low state It is considered to be in a released contact state.

In this case, when it is detected as a contact state in step 401, the first microcomputer 11 reads and stores the counter value at the point of contact in step 402, and reads the counter value through the P _B port in step 403. Serial number of passwords are sent. At this time, the secret code transmission form is composed of a total of 18 bits, such as the start 1 bit + count value (password) 16 bits + stop bit 1 bit ＂, the data type uses a Non-Return to Zoro (NRZ) form. In this case, when the bit data transfer rate (bps) is 300 μsec, the total password transfer time is 5400 μsec. This data type is used by the first microcomputer 11 and the second microcomputer 21 in the same manner.

As described above, after the first microcomputer 11 transmits the password in step 403, it is checked whether the transmission is completed in step 404. If not, in step 405, the first microcomputer 11 checks whether the contact is released. In this case, when the contact is released, the process returns to step 401 to designate a new password in the contact state, and returns to step 403 to repeat the password transmission process in the contact state. At this time, when the contact is released in step 405, the logic FLOW signal is received through the P _B port. However, depending on the logical state of the password, a logical flow level appears at the P _B port during data transmission and reception. Accordingly, the first microcomputer 11 and the second microcomputer 21 may have a logic low level when the P _B port and the P _H port remain longer than a data transfer period (18 bit data transfer period = 5400 µsec), respectively. The contact is considered to be released. That is, since the 16-bit counter has a data value of "0000 _H " in the initialization state, a logic fellow signal may be generated at the P _B and P _H ports up to 5400 µsec after contact.

When the first microcomputer 11 transmits a password through the port P _B after the initial contact as described above, the first microcomputer 11 is applied to the P _H port of the second microcomputer 21 through the CB2 terminal and the CH2 terminal of the contact unit 30. In this case, the second microcomputer 21 enters the reception standby state after detecting the contact state in step 501 and receives the data received through the P _H port as a password in step 502. The second microcomputer 21 performs steps 503 and 504 to check the state of contact within the data transfer period as described above. That is, the second microcomputer 21 receives through the P _H port from the time when the first microcomputer 11 starts transmitting the password. If the P _H port is kept in a low state so that the data transmission period is exceeded, the second microcom 21 is transmitted. Contact is deemed to have been released prior to receiving a valid password and the previously held password is considered valid. However, when the second microcomputer 21 receives the received password, the received password is stored and the received password is retransmitted again through the P _H port in step 505. In this case, the 16-bit data including the 16-bit password and the start bit and the stop bit are stored and transmitted in the same manner as that of the password transmission of the first microcomputer 11 described above. Therefore, the second microcomputer 21 is 505 - while performing the 507 step, to be regarded as the transmission of the P _H port is a normal password is not continued on the "low" level to the data transmission period elapses. However, if the contact is released during transmission in step 507, the current number is ignored and the previous password is regarded as valid and the process returns to step 501. In this case, the reason for retransmitting the password received by the second microcomputer 21 is to confirm whether the password transmitted from the first microcomputer 11 and the password received from the second microcomputer 21 are the same number. Thereafter, the second microcomputer 21 checks whether the next data is input in step 508.

When the password received by the second microcomputer 21 is retransmitted through the P _H port, it is applied to the P _B port of the first microcomputer 11 through the CH2 terminal and the CB2 terminal. Then, the first microcomputer 11 receives the signal through the P _B port in step 406. In this case, the base unit 10 and the hand set unit 20 perform the steps 406-408. If separated, the current number is ignored and the previous password is considered valid and the process returns to step 401 above. However, if the reception of the password is completed within the data transmission period in step 407, the first microcomputer 11 transmits the password and the second password through steps 403 to 405 in step 409. It is sent from the microcomputer 21 and performs steps 406 to 408 to check whether the received password is the same. At this time, if the two numbers are different in step 409, since the password to be designated is wrong, the process returns to step 402, reads and stores the new count value of the counter, and starts the password transmission process again. However, if the password transmitted in step 409 and the received password are the same, the first microcomputer 11 designates the corresponding number as a password in step 410 and ends.

At this time, after the second microcomputer 21 transmits the received password, the second microcomputer 21 checks whether a new password is received through the P _H port in step 508, and if a new password is not received through the P _H port (509). In step), it checks whether a certain time has elapsed. Here, the predetermined time is a time that may include enough time to compare the password received by the first microcomputer 11 with the transmitted password and determine whether there is the same, and to read and transmit the value of the new counter when different. it means. Therefore, the second microcomputer 21 to be considered, and the 502 phase that is transmission of a new password occurs a change in the state of P _B port for the time, to examine a change in the state whether or not P _B port during said predetermined period of time Go back. That is, when the password transmitted by the first microcomputer 11 and the received password differ, the first microcomputer 11 is designated by the base unit 10 and the handset unit 20, respectively. The value of the new counter is transmitted as a password, and the second microcomputer 21 recognizes it through steps 508 to 510 and performs an operation for specifying a new password again. However, if the second microcomputer 21 does not receive new data such that the time enough to receive the data transmitted by the first microcomputer 11 has elapsed, it is recognized in step 509. Accordingly, the second microcomputer 21 considers the password specified in the base unit 10 and the password received and stored in the handset unit 20 to be the same. Specify and exit.

The above password assignment operation is performed whenever the handset unit and the base unit are separated and in contact.

The operation of specifying the password will be described assuming that the counter value inside the first microcomputer 11 is '1989' when the handset unit 20 and the base unit 10 come into contact with each other. At this time, the password transmitted by the first microcomputer 11 is '1989'. At this time, the first microcomputer 11 transmits # 1989 'through the P _B port, and the second microcomputer 21 receives # 1989' through the P _H port and stores it. The second microcomputer 21 transmits the received and stored password '1989' to the first microcomputer 11 again. At this time, the first microcomputer 11 designates this as a password when the transmitted password '1989' and the received password are the same. If the new password is not received within a predetermined waiting time after the received password is transmitted, the second microcomputer 21 designates "1989" which is currently received and stored as the password. At this point, if the base unit and the handset unit are separated at some point during the above process, all the processing up to that point is invalidated and the previous password is valid.

As described above, by additionally designating a password by performing data communication between the base unit and the handset unit in the wireless telephone, additional components for specifying a password can be removed, and the password is specified using a counter. The number of passwords can be extended in various ways according to the number of bits in the counter, and the password value is assigned to the count value at that time whenever the base unit contacts the handset unit. There is an advantage that can eliminate the risk.

Claims (2)

Built-in counter for counting a predetermined timer interrupt period, and comprises a base unit for performing wired communication with the switch, a handset unit for performing wireless communication with the base unit, and contact terminals, between the base unit and the handset unit. In the password designation method of a wireless telephone having a contact portion for generating a status signal of the presence or absence of contact, the step of inspecting the state of the contact portion and each of the base unit and the handset unit to check whether there is a contact, and the separation during the inspection process Recognizing a transition of a contact state in a state, the base unit storing the value of the counter as a password and transmitting the same to the contact unit, and the handset unit storing the data received through the contact unit as a password; After performing the procedure, the handset unit Retransmits the received data to the contact, and receives the password that the base unit retransmits through the contact; and after performing the process, compares the password transmitted and received by the base unit to update the corresponding number. The password designation method of the wireless telephone, characterized in that the handset unit designates a new password and terminates the stored number when no new data is received through the contact unit after a predetermined time elapses. . The password designation method of claim 1, wherein the process of transmitting the password by the base unit and the handset unit is performed by converting the data into serial data of an asynchronous communication method through the communication terminal of the contact unit.

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