KR100314187B1 - The receiving information devices of cellular or PCS phones, and control method thereof - Google Patents

Abstract

The present invention relates to an incoming call notification device for a mobile phone and a control method thereof. When the user is difficult to recognize whether a mobile phone is received in a public place or the like, the mobile phone is installed adjacent to the mobile phone to receive an incoming signal from the user's mobile phone. It is configured to operate only by receiving the incoming signal from the incoming signal repeater 100 and the incoming signal repeater 100 to detect the incoming signal from the mobile phone to be sent when the incoming coded to the incoming notification 200, Comparing with the unique code value that is already set, if it matches with each other, it is composed of a receiving notification 200 to be notified to the user by the light emission and vibration is carried or mounted in a place where the user can easily recognize, 32-bit Receive code or other signals from other party's incoming signal repeater 100 by using code values Possible to improve the reliability by preventing a malfunction caused by, and which can be a simple structure to increase the productivity, so making easy to, it is characterized by configured to enable the size and weight of the product to be easy to carry.

Description

Incoming notification device for mobile phone and its control method {The receiving information devices of cellular or PCS phones, and control method}

The present invention relates to an incoming call notification device for a cellular phone and a control method thereof for detecting an electric field of an incoming signal transmitted when an incoming call is received to a user and informing the user of the incoming call of the cellular phone.

Conventionally, as shown in FIG. 7, a detection circuit S5 for detecting an outgoing radio wave when the telephone S1, the transmitter S2, the portable receiver S3, the reception antenna S4 for receiving radio waves, and the telephone S1 are received. ), An address setting switch S6 for setting an address by an external operation, an encoder S7 for generating a selected address code, a modulation circuit S8 for making the address code a code signal, an amplifying circuit for amplifying the code signal ( S9), a transmitting antenna S10 for transmitting the amplified code signal with a weak radio wave, a receiving antenna S12 for receiving the code signal transmitted from the transmitting antenna S10 of the transmitter S2, and amplifying the received code signal. Amplification circuit S13, a demodulation circuit S14 for reproducing the amplified code signal with an address code, an address setting switch S15 for setting the same address code as that of the transmitter S2 by external operation, and address setting Selected by the switch S15 A decoder S16 for outputting a coincidence signal when the dress code and the address code demodulated and reproduced in the demodulation circuit S14 match, a drive circuit S17 for operating the vibrator upon input of the coincidence signal, and a vibrator S18. It consisted of. In the operation of the conventional incoming call notification device configured as described above, when the reception antenna S4 detects the radio wave transmitted when the telephone S1 is received, the detection circuit S5 detects the signal and sends the signal to the encoder S7. The encoder S7 generates a code corresponding to the value selected by the address setting switch S6, and the address code generated by the encoder S7 transmits the code signal through the modulation circuit S8. The modulated code signal is amplified by the amplifying circuit S9 and radiated from the transmitting antenna S10. The radiated code signal is captured through the receiving antenna S12 of the portable receiver S3, and the captured code signal is amplified by the amplifying circuit S13, reproduced by an address code in the demodulation circuit S14, and the reproduced address. The code is compared with the address code selected by the address setting switch S15 at the decoder S16. When both address codes match, the decoder S16 outputs a matching signal to the driving circuit S17 and the matching signal. The drive circuit S17 drives the vibrator S18 to notify the user of the arrival of the cellular phone S1.

However, since the outgoing radio wave is detected when the incoming call is received from the phone S1, but the magnitude of the radio wave is detected, the outgoing radio wave from the phone S1 is minute and there is a possibility of detection or malfunction due to other signals. In order to prevent the malfunction of the portable receiver (S3) due to the transmitter (S2) of the other person, but artificially set the address from the outside, the range of the address is limited, the case may be the same as the address selected by others There was a disadvantage of malfunction.

The present invention has been invented to solve the above problems, while detecting a signal from the mobile phone to improve the reliability by preventing a conventional frequently occurring malfunction, and the positioning signal from the mobile phone and In order to detect an incoming signal with a relatively long outgoing signal, the method compares the outgoing duration of a signal from a mobile phone by using the difference in the outgoing duration of an incoming signal. At the same time, when detecting the strength of the electric field, it is possible to capture minute signals that are difficult to detect.Incoming only when the codes coincide with each other by assigning unique codes to one set of incoming signal repeater and incoming notification period. By enabling the notifier, a signal can be input from another person's incoming signal repeater. In order to prevent malfunctions, the recipient notification system uses 32-bit code to avoid duplication of code with others, and separates code values into upper and lower codes so that upper and lower codes are inverted. It is an object of the present invention to provide a call notification device for a cellular phone and a control method thereof so that an error in a code due to noise or the like can be immediately detected.

1 is a block diagram of an incoming signal repeater of the present invention;

2 is a block diagram of a call notification of the present invention;

3 is an incoming signal repeater circuit diagram of the present invention;

4 is a receiver report circuit diagram of the present invention;

5 is a flow chart of the code generator of the present invention,

6 is a code comparison flowchart of the present invention;

Fig. 7 is a block diagram of an incoming call notification device of a conventional telephone.

<Signs and explanations of the main parts of the drawings>

100: incoming signal repeater 200: incoming call notification

2: RF switch 3: code generator

4: Modulator 8: MIX

10: waveform shaping unit 11: code comparison unit

As shown in FIG. 1 and FIG. 2, the present invention is composed of an incoming signal repeater 100 and an incoming notification receiver 200. The incoming signal repeater 100 includes a detector 1, an RF switch 2, and a cord. A generator 3, an IC driver 3-1, a modulator 4, an oscillator 7-1, a sensing antenna A1, a transmitting antenna A2, and the like, and the incoming call receiver 200 receives the signals. Antenna (A3), amplifier (5), BPF (6), oscillator (7-2), MIX (8), detector (9), waveform shaping unit (10), code comparison unit (11), light emitting unit (12), the vibration unit 13, and the like, and detailed descriptions of the respective circuits are as follows.

Looking first at the configuration of the present invention,

As shown in FIG. 3, the detector 1 is for detecting a signal from a mobile telephone. The sensing antenna A1 and the capacitor C1 are connected in series, and the capacitor C1 is again connected to the IC U1. It is connected in series with terminal 3. Terminal 2 of IC U1 is connected to resistors R1 and R2 and terminal 3 of IC U2 in RF switch 2, and terminal 1 of IC U1 is resistor R2 and RF switch. It is connected to the first terminal of the IC U2 in (2) and the grounded resistor R3.

The RF switch 2 is a circuit for notifying the code generator 3 of the signal input. The first and third terminals of the IC U2 are the first of the IC U1 in the detector 1, respectively. And Terminal 2 are connected, Terminal 2 is grounded, and Terminal 5 is connected to the power supply VCC1 through the switch SW1. And terminal 4 is branched, one side is connected to the power supply (VCC1) through the resistor (R4) and the switch (SW1), the other side is connected to terminal 4 of the IC (U3) in the code generator (3) The capacitor C2 connected to the switch SW1 is grounded.

The code generator 3 is a circuit for generating a code. The terminal 1 of the IC U3 is connected to the power supply VCC1 through the switch SW1 and the terminal 4 is the IC U2 in the RF switch 2. Terminal 4 and terminal 8 of the IC (U3) is grounded, and terminal 5 of the IC (U3) is connected to the modulator (4) through the resistor (R8), to drive the IC (U3) Is connected in parallel with the emitter-base circuit of resistor R5 and transistor Q1, and one side of resistor R5 and the emitter side of transistor Q1 are in series with DC power supply VCC1 through switch SW1. The resistor R6 connected to terminal 6 of the IC U3 is connected in series to one side of the resistor R5 and the base side of the transistor Q1, and one side of the capacitor C3 is the collector side of the transistor Q1. And an IC driver 3-1 grounded at the other side.

The modulator 4 is a circuit for modulating the data code generated by the code generator 3 at a suitable frequency so that the called receiver can receive it. One side of the capacitor C4 has a resistance R8 in the code generator 3. ) And the other side is grounded. One side of the resistor R9 is also connected to the resistor R8 in the cord generator 3, the other side is connected to each side of the variable capacitor U4 and the capacitor C5, and the other side of the variable capacitor U4 is grounded and a capacitor. The other side of C5 is connected to the oscillator 7-1 in the modulator 4, in order to generate an appropriate frequency, the coil L1 and the resonator S1 are connected in series, and the coil (1) is connected to the other side of the resonator S1. L2) is connected to the capacitor C6, and the other side of the coil L2 connected to the resonator is connected to the base side of the capacitor C7 and the transistor Q2, and the other side of the capacitors C6 and C7 is grounded and the resistor R10 is connected. Is connected in parallel between the collector of transistor Q2 and the base, and the collector side of transistor Q2 is connected to the strip line in coil L1 and the transmission antenna A2, and between the collector and the emitter a variable capacitor ( C8) is connected in parallel and the emitter side includes a grounded oscillator 7-1.

In order to emit the modulated code signal, the transmit antenna A2 is composed of an inductive coupling of the strip line connected to the modulator 4 and the condensers C10 and C11. R7) is connected to the collector side of transistor Q1 in code generation section 3 and grounded via capacitor C9.

As shown in FIG. 4, the reception antenna A3 of the incoming call receiver 200 includes a loop antenna and condensers C21 and C22, and one side of the condenser C21 and C22 is a loop antenna and the other side is grounded. Is connected, the contact of the variable capacitor (C22) and the antenna is connected to the amplifier (5).

The amplifier 5 amplifies the signal captured by the antenna so as to process the signal even when a minute signal is captured. One side of the capacitor C23 is connected to the antenna and the other side is connected to the base side of the transistor Q3. do. The base of the transistor Q3 is connected to the grounded diode D1, and one side of the transistor Q3 is connected to the ground through the resistor R24, and the other side of the transistor Q3 is connected to the ground through the capacitor C25. The diode D1 connected to the base side of the transistor Q3 is connected in the reverse direction, the emitter side of the transistor Q3 is grounded, and the collector side is connected to the emitter side of the transistor Q4. In the transistor Q4 in which the emitter side is connected to the collector side of the transistor Q3, one side of the base side is grounded through the capacitor C24, and the other side thereof is connected to the DC power supply VCC2 through the resistor R21 and the switch SW2. The collector side is connected to the BPF 6.

The BPF 6 is a circuit for detecting a signal in a required frequency domain and is composed of a coil L3, a capacitor C26, and a resistor R25 and connected in parallel with each other. The contact connected to the collector side of the transistor Q4 in the amplifier 5 is again connected to the MIX 8, and the contact between the resistor R24 and the capacitor C25 in the amplifier 5 is a resistor R22 and a switch. It is connected to the DC power supply VCC2 through SW2.

The configuration of the oscillator 7-2 is the same as the oscillator 7-1 described above, one side of the output side is connected to the MIX (8), the other side is branched through the coil (L7), one side is grounded coil (C34) ) And the other side is connected to the resistor (R29) connected to the detector (9).

MIX (8) is a circuit for mixing the input signal passed through the BPF (6) and the signal applied from the oscillator (7-2), one side of the capacitor (C27) is connected to the BPF (6) and the other side It is connected to the base side of transistor Q5. The base side of the transistor Q5 connected to the BPF 6 through the capacitor C27 is connected to the oscillation unit 7-2 again through the capacitor C29, and one side of the transistor Q28 is grounded through the resistor R26. The other side is connected to the DC power supply VCC2 through a resistor R23 and a switch SW2. The emitter side of transistor Q5 is grounded, the collector side is connected to coil L4, capacitor C30, resistor R27, and coil L4, capacitor C30, resistor R27 are connected in parallel to each other. do. The contact between the collector side of the transistor Q5 and the elements L4, C30, and R27 is connected to the detector 9 again, and the other contact of the coil L4, the capacitor C30, and the resistor R27. Is connected to the DC power supply VCC2 through a resistor R23 and a switch SW2.

The detector 9 is a circuit for detecting the received preprocessed signal so that the waveform shaping unit 10 can process the waveform. The terminal 1 of the IC U5 is connected through the capacitor C49 and the switch SW2. It is connected to the DC power supply (VCC2), and the terminal 2 is connected to the waveform shaping portion (10). Terminal 3 is connected to DC power supply (VCC2) through capacitor (C48) and switch (SW2), and terminal 4 is branched so that one side is connected in parallel with resistor (R30), coil (L8), and capacitor ( C43) is connected to terminal 5 and the other side is connected to the DC power supply (VCC2) through the switch (SW2). Terminal 5 is branched so that one side is connected to terminal 4 through the resistor R30, coil L8, and capacitor C43, and the other side is branched again so that one side is connected to capacitor C44 and the other side is diode ( The capacitor C44 is again connected in series to one side of the variable capacitor C45, and the other side of the variable capacitor C45 is branched so that one side is grounded through the capacitor C47 and the other side is connected to the capacitor C46. Connected to terminal 16 through In addition, the anode side of the diode D2 connected to the terminal 5 is connected to the terminal 16 of the cathode side. Terminal 6 is connected to terminal 8 through the capacitor (C42), terminal 7 is connected to the switch (SW2) and terminal 8 is connected to terminal 9 through the capacitor (C41). Terminal 10 is connected to the DC power supply through the capacitor (C40) and the switch (SW2), terminal 11 is connected to the MIX (8) through the capacitor (C39). Terminal 12 is grounded through a capacitor C38, and terminal 13 is connected to a DC power supply VCC2 through a capacitor C37 and a switch SW2. Terminal 14 is directly grounded, terminal 15 is connected to the switch (SW2) through the capacitor (C36), and is connected to the resistor (R29), the capacitor (C35).

The waveform shaping unit 10 is a circuit for shaping the detected signal into a square wave. The resistor R31 and the capacitor C50 are connected in parallel, and one side is connected to the detector 9 and the resistor R32 and the other is grounded. do. The other side of the resistor R32 connected to the detector 9 is connected to each side of the resistor R33 and the condenser C52, and the other side of the resistor R33 is branched so that one side is the fifth of the IC U6-1. The terminal and the other side are connected to the ground through a condenser C51. The other side of the capacitor C52 is connected to terminal 7 of the IC U6-1, and terminal 6 of the IC U6-1 is branched so that one side of the capacitor C52 is connected to the terminal 7 of the IC U6-1 through the resistor R35. Terminal 1 is connected, and the other side is connected with terminals 1 and 2 of the IC U7 through the resistor R34. Terminal 7 of IC (U6-1) is branched so that one side is grounded through capacitor (C53) and the other side is connected via resistor (R36) terminal 3 of IC (U7) and the other side is connected to IC (U6-2). It is connected to terminal 3 of respectively. Terminal 2 of IC U7 is connected to terminal 2 of IC U6-2, and terminal 8 of IC U6-2 is connected to switch SW2. And terminal 4 of the IC (U6-2) is grounded and terminal 1 is connected to the code comparison unit (11).

The code comparison unit 11 is composed of an IC U8, and the first terminal of the IC U8 is connected to the DC power supply VCC2 through the switch SW2, and the third terminal is connected to the light emitting unit 12. . Terminal 4 is connected to the waveform shaping unit 10 and terminal 5 is connected to the vibration unit (13). Terminal 7 is grounded via switch (SW3) and terminal 8 is directly grounded.

The light emitting unit 12 is a circuit for emitting light when a signal from the code comparing unit 11 is applied. One side of the resistor R37 is connected to the code comparing unit 11 and the other side is a base side of the transistor Q7. Is connected to. The emitter side of transistor Q7 is connected to DC power supply VCC2 via switch SW2, and the collector side is connected to LED.

The vibrator 13 is a circuit for vibrating operation when a signal from the code comparator 11 is applied. One side of the resistor R39 is connected to the code comparator 11 and the other side is a base side of the transistor Q8. Is connected to. The emitter side of the transistor Q8 is connected to the DC power supply VCC2 through the resistor R38 and the switch SW2, and the collector side is connected to the motor M.

Looking at the operation of the present invention configured as described above,

As shown in FIG. 3, when the electric field signal transmitted from the mobile phone is input through the sensing antenna A1, the number 3 of the IC U1 is controlled by the coil La and the capacitor C1 for controlling the overcurrent and the overvoltage. Input is made to the terminal. IC (U1) is a device composed of two Schottky diodes. It is used to detect a wide signal band from small signal to large signal. When signal is input to terminal 3, it rectifies and detects this signal and outputs it to terminal 1. do. The voltage outputted to terminal 1 is again branched by resistors R1, R2, and R3 to be input to terminals 1 and 3 of IC U2 in RF switch 2, respectively.

When the signal detected by the detector 1 is inputted to the first and third terminals of the IC U2 in the RF switch 2 adopting the FSK method, the fourth terminal of the IC U2 is always low. While outputting, the input signal is amplified by the IC U2 by the resistors R1, R2, R3, and R4 and the capacitor C2 to output high.

After checking whether or not a signal is input from the RF switch 2 and if the input signal satisfies a condition already programmed, the code generator 3 for generating a code is an RF switch 2 as shown in FIG. When the signal is input to terminal 4 of IC (U3), IC (U3) first judges the signal input (22), but if there is no signal input, it goes to standby state and if there is signal input, the signal lasts longer than 150ms. It is determined whether or not (23). In this case, the reason why the signal is continued for more than 150ms is that the signal transmitted by the mobile phone includes not only the electric field signal generated when the incoming call is received but also the signal for positioning. The length of the positioning signal is relatively longer than the length of the electric field signal generated at the incoming call. This is to prevent malfunction due to the positioning signal because it is short. If the signal does not continue for more than 150ms, the signal waits again, and if the signal continues for more than 150ms, a unique 32-bit data code is generated (24). By comparing the inverted values of the upper 16 bits and the lower 16 bits of the code, the upper 16 bits and the lower 16 bits form a data value so that they can be inverted from each other. Once a data code is formed, a 400 ms delay (25 In order to synchronize, the synchronization signal bit '0' is transmitted to the incoming call signal unit 10 (26). When the synchronization signal is transmitted, it transmits the start bit '1' indicating the start of data (27), but after transmitting the long signal considering the noise mixed or delayed due to the obstacle between the incoming signal repeater and the incoming notification. In order to count the transfer bits of 32-bit data, 32 is stored in the counter (28). When 32 is stored in the counter, one bit is shifted and stored in a register (29) in order to transmit a data code, and then data is transferred to the called receiver (30). After the transmission of the one-bit data code, the value of the counter is decremented by one (31), and it is determined whether the value of the counter is zero (32). If the value of the counter is not 0, the next 1 bit is shifted and stored (29), then data is transferred (30), the value of the counter is decreased by 1 (31) again, and it is determined whether the value of the counter is 0 ( 32) The operation is repeated until all 32-bit data codes are transmitted. When all 32-bit data codes are transmitted and the value of the counter reaches zero, it is determined whether the user is using the mobile phone and the timer is turned on (33) for a predetermined time interval. It is determined whether the signal input to the code generator 3 continues in the on state of the timer (34), and it is determined whether the cellular phone is used. When the user uses the cellular phone, the input of the signal is continued and the standby state is established. After the input of the signal, the timer time is determined (35). If the timer has not elapsed, it is determined whether the signal is continued (34) again. If there is no signal, the timer elapses again. It is repeatedly judged whether the signal is continuous and the time elapses of the timer. If there is no signal and the timer elapses, the signal returns to the standby state for receiving the signal again. The data code signal formed through the above process is output to terminal 5 of the IC U3 and applied to the modulator 4 through the resistor R8. At the same time, in the IC driver 3-1 for driving the IC U3, when the base of the transistor Q1 connected to the sixth terminal of the IC U3 through the resistor R6 becomes high, the transistor Q1 is turned on. The emitter and the collector are turned on to drive the IC U3 and apply power to the modulator 4 through the resistor R7 and the strip line.

When the code signal generated from the code generator 3 is input, the capacitor C4 removes unnecessary high frequency and noise and applies the code signal to the variable capacitor U4 through the resistor R9. The code signal applied to U4 is again modulated by being combined with the signal generated by the oscillator 7-1 through the capacitor C5.

When the code signal is input to the oscillator 7-1 through the capacitor C5, the signal generated from the resonator S1 may be different from the code signal input through the coils L1 and L2, the resistor R10, and the transistor Q2. Add up and modulate the code signal by causing a frequency shift around the appropriate frequency.

The transmission antenna A2 connected to the collector of the transistor Q2 in the oscillator 7-1 forms a loop antenna by inductive coupling of the strip line and the capacitors C10 and C11 to radiate a modulated signal. do.

As shown in FIG. 4, the coded modulated signal is input to the amplifier 5 through the loop antenna of the receiving antenna A3 and the matching circuit of the capacitors C21 and C22, and the input signal is connected to the capacitor C23. Branched through, one side is applied to the base side of the transistor Q3, and the other side is applied to the transistor Q4 through the resistor R24 and the coil L3 in the BPF 5. At this time, the transistors Q3 and Q4 amplify the current and the voltage, respectively.

When the signal amplified by the amplifier 5 is applied to the BPF 6, the coil L3, the capacitor C26, and the resistor R25 of the BPF 6 act as a filter to tune the frequency band.

The signal generated from the oscillator 7-2 is divided into two and one side is applied to the MIX 8 to be mixed with the signal applied from the BPF 6, and the other side is the coil L7, the capacitor C34, and the resistor R29. Is applied to the code comparator 9 through e.

The signal input from the BPF 6 is passed through the condenser C27, and the signal input from the oscillator 7-2 is applied to the base side of the transistor Q5 through the capacitor C29, and the two met at the base side. The signal is mixed in the transistor Q5, and the lower intermediate frequency is selected and applied to the code comparator 9 through the resistor R26, the coil L4, the capacitor C30, and the resistor R27.

When the mixed signal selected by the MIX 8 is applied to the terminal 11 of the IC U5 through the capacitor C39, the required intermediate frequency is selected by the oscillation frequency at the terminals 4 and 5 of the IC U5, The 6th, 7th, and 8th terminal low pass and amplify the input signal through 11. When a signal is input to terminal 9 through the capacitor C41, it is modulated and demodulated in IC U5. The demodulated signal is used as the AFC of terminal 5, and the process described above is performed at terminal 2. The rough AF signal is output to the waveform shaping unit 10.

When the signal from the detector 9 is input through the resistor R31, the capacitor C50, and the resistor R32, the active unit includes the IC U6-1, the resistors R33 and R35, and the capacitors C51 and C52. Reselect the signal from the filter and output it through terminal 7 of IC (U6-1). The signal output from terminal 7 is applied to terminal 3 of IC U7 and terminal 3 of IC U6-2 through resistor R36. The signal input to terminal 3 of IC (U7) is rectified as square wave and applied to terminal 2 of IC (U6-2). This signal is amplified by IC (U6-2) again to terminal 1 Through the code comparison unit (U11) is input.

As shown in FIG. 6, when a signal is input from the waveform shaping unit 10 to the terminal 4 of the IC U8, the code comparing unit 11 waits for input of the signal, and inputs the signal if there is an input. It is determined whether the received signal lasts for more than 150 ms (43). If there is no input of the signal or the duration of the signal is not 150 ms, the signal input waits again (42). When the input signal continues for more than 150ms, the input of the start bit signal is waited (44). When the start bit is input, 32 is stored (45) in the counter to count the 32-bit data code. After storing 32 in the counter, data is received (46) and it is determined whether it is proper data (47). If the received data is not appropriate, the signal input is waited again (42). After shifting (48) the data into a register and decrementing the counter by one (49), it is determined whether the value of the counter is zero (50). If the data value is not 0, the data is received 46 again and the above process is repeated until the counter value becomes 0. When the value of the counter reaches zero, it is determined whether the upper 16 bit code value of the received data code and the inverted lower 16 bit code value stored in the register match (51). If the upper and lower code values do not match, the signal input waits again (42). If the code values match, the received code value is compared with the already set unique code value (52). If the received code value does not match with the unique code value already set, it waits for signal input again (42). If both code values match, signals for driving the LED and the motor are set to 5 and 3 of the IC (U8), respectively. Output through No.1 terminal to turn on LED and motor (53, 54) and turn on timer to operate LED and motor at regular intervals. It is determined whether there is a key input from the user while the LED and the motor are being driven (56), and when the key is input, the terminals 5 and 3 of the IC (U8) are used to output the signal immediately to turn off the LED and the motor (58, 59). Will stop. If there is no key input from the user, it is determined that the time elapses of the timer (57). If the time has not elapsed, a repetitive operation of waiting for the key input from the user (56) and determining the time elapse of the timer (57) is executed. When the timer elapses during the execution of the repetitive operation, the output of the terminals 5 and 3 of the IC U8 is stopped to turn off the LEDs and the motors (58, 59).

When a voltage is applied from the code comparing unit 11 to the base side of the transistor Q7 through the resistor R37, the emitter and the collector of the transistor Q7 are turned on so that the LED is turned on and emits light. You will be notified visually.

When a voltage is applied from the code comparing unit 11 to the base side of the transistor Q8 through the resistor R39, the emitter and the collector of the transistor Q8 are turned on so that the motor is turned on and vibrates so that the user can receive the mobile phone. You will be noticed happier.

The present invention detects the signal from the mobile phone as described above, but by using a method of comparing the duration of the signal rather than the magnitude of the signal can prevent the operation by the positioning signal sent by the mobile phone, fine The signal can also be detected, and in forming the data code for the incoming call, the 32-bit code of the upper 16 bits and the lower 16 bits is formed so that code duplication with others can be avoided, and the upper 16 bits and the lower 16 bits are different from each other. By having the same value inverted, it is easy to detect the error of the code that can occur during transmission, and it is easy to produce by using the existing IC, as well as easy to carry by miniaturization and light weight.

Claims (2)

Incoming signal repeater for detecting incoming signal from cellular phone and transmitting code signal to incoming call notification to notify user when incoming of mobile phone, and received code signal received by incoming signal repeater In the incoming call notification device for a mobile phone and a control method thereof, comprising: a call notification device for comparing a pre-selected code with a pre-selected code to notify the user of the incoming call with light emission and vibration. It consists of IC (U1) and resistors (R1, R2, R3), so that the signal captured by the antenna is rectified and detected through IC (U1), branched by resistors (R1, R2, R3) and RF switch (2). A detector (1) circuit for applying It consists of IC (U2), resistor (R4) and capacitor (C2) but connected to the detector (1) to amplify the signal input from the detector (1) to IC (U2) and resistor (R4) to high RF switch (2) circuit adopting FSK method to output IC driving unit 3-1 which comprises resistors R5 and R6, transistor Q1, and capacitor C3 to drive IC U3, and drives IC U3 when the base side of the transistor becomes high; , The IC driver 3-1 includes the IC U3 and the resistor R8, and is driven by the IC driver 3-1 to modulate the code generated by the IC U3 through the resistor R8. A code generator (3) circuit outputted to the unit (4), The resonator (S1) and the resistor (R10), coils (L1, L2), capacitors (C6, C7), variable capacitor (C8), transistor (Q2) consisting of a code and a resonator (C4) input through the capacitor (C5) An oscillator 7-1 circuit configured to mix the signal oscillated at S1 through the transistor Q2, the oscillator 7-1, and is connected to the code generator 3 and connected to the resistor R9, Composed of variable capacitor U4 and capacitors C4 and C5, the code inputted from the code generator 3 to the variable capacitor U4 is applied to the oscillator 7-1 through the capacitor C5 and modulated. A modulator 4 circuit for outputting a code signal to a transmission antenna A2; Connected to the modulator 4 and composed of inductive coupling of the strip line and the capacitors C10 and C11 to radiate the code signal applied to the strip line through the capacitors C10 and C11. An incoming signal repeater 100 composed of a transmitting antenna A2 for transmitting; It is connected to the receiving antenna A3 and consists of the transistors Q3 and Q4, the diode D1, the resistor R24, and the capacitors C23, C24 and C25, and the transistors Q3 and Q4 are respectively the receiving antennas (A). An amplification unit 5 circuit for amplifying the current and voltage input through A3) and outputting it to the BPF 6; It is connected to the BPF 6 and the oscillator 7-2, respectively, and is composed of a transistor Q5, resistors R26 and R27, coils L4, and capacitors C27, C28, C29, and C30 to mix signals. A MIX (8) circuit for mixing the signals input from the BPF 6 and the oscillator 7-2 to the detector 9 by mixing them in the transistor Q5; It is connected to the oscillator (7-2), MIX (8), waveform shaping unit (10), and IC (U5) and condenser (C35, C36, C37, C38, C39, C40, C41, C42, C43) to detect a signal. , C44, C46, C47, C48, C49, variable capacitor (C45), coil (L8), resistor (R30), diode (D2), the first intermediate frequency selected from MIX (8) is IC (U5) When input to terminal 11 of, input intermediate frequency by oscillation frequency at terminal 4 and terminal 5 and low pass and amplify second intermediate frequency at terminal 6, 7, and 8, and oscillator (7-2) To filter the intermediate frequency by frequency modulation and use the AFC signal at terminal 5 and the AF signal at terminal 2 through the demodulation in IC U5. A detector (9) circuit for IC (U6-1, U6-2, U7), resistors (R31, R32, R33, R34, R35, R36) and capacitors (C50, C51, C52, and C53, but the signal input to the capacitor C50 in the detector 9 is amplified in the IC U6-1, rectified in the IC U7, and then again in the IC U6-2. A waveform shaping unit 10 circuit amplified and applied to the code comparing unit 11, It is connected to the waveform shaping unit 10, the light emitting unit 12, and the vibration unit 13, and composed of one IC (U8) to compare the code input from the waveform shaping unit 10 with a predetermined code and invert each other. A code comparison unit 11 for determining whether to output a signal to the light emitting unit 12 and the vibrating unit 13 by comparing the upper and lower codes having It is connected to the code comparator 11 and consists of a resistor R37, a transistor Q7, and an LED. When a signal is applied from the code comparator 11 to the base side of the transistor Q7 through the resistor R37, an emitter and A light emitting unit 12 circuit in which the collector is turned on so that the LED emits light by DC power supply VCC2; When the signal is connected to the code comparator 11 and composed of resistors R38 and R39, a transistor Q8 and a motor and a signal is applied from the code comparator 11 to the base side of the transistor Q8 through the resistor R39. An incoming call notification device for a mobile phone, characterized in that the emitter and the collector are connected to each other and are composed of a call notification device (200) consisting of a vibration part (13) circuit which causes the motor to vibrate by a DC power supply (VCC2). A call notification device for a cellular phone for notifying a user of incoming or outgoing calls by judging whether the incoming code is the same code from the incoming signal repeater by selecting the same code in the incoming call relay and the incoming notification period. In the control method, The incoming signal repeater 100 processes the detected incoming signal using the FSK method and generates a 32-bit code according to the signal. However, the incoming signal repeater 100 determines whether the input signal lasts for a predetermined time. After transmitting 10 times, transmit the 32-bit code that has the same value for each of the start bit and the upper and lower 16 bits to be inverted from each other, wait for the detected incoming signal to continue, and wait for the incoming signal to be detected again through the timer. State, and the generated code is modulated into a code signal and transmitted. When the code signal is input from the incoming signal repeater 100, the incoming notification device 200 amplifies the received code signal and demodulates the square wave code through processing such as filtering, modulation, and detection, and the signal also lasts for a predetermined time. If the start bit is input, the code is judged first. If the start bit is input, the code is judged and stored. If all 32 bit codes are stored, the upper and lower 16 bit code values of the stored codes are compared with each other. If it satisfies, the control of the incoming call notification device for a mobile phone, characterized in that if both code values are the same compared to the already set unique code, light emission and vibration are started and light emission and vibration are stopped through the time input of the key input and the timer. Way.