KR910001733B1 - Charging circuit in cordless telephone - Google Patents

Abstract

The charger controls the power providing to a transmission and a reception modules of the main body when a handset is placed on the main body so that the battery in the handset can be charged quickly. The charger includes a first and a second power input terminals (1,2) for providing the charge current to the battery, a power switch (SW1) for switching the first power (Vcc) providing to the transmission or reception modules, an inverter for inverting the charge completion signal and transmitting the inverted and non inverted charge signals to the first input terminal of a microcomputter (50), a mode selection switch (SW2) for transmitting a mode selection signal generated by user's choice and provided to a second input terminal (I2) of the microcomputer (50) and a first and a second switching circuits for controlling the power flowing into the transmission and reception modules.

Description

Transmission / reception power cutoff circuit when charging a wireless

1 is a block diagram of a wireless telephone.

2 is a conventional power charging circuit.

3 is a block diagram of a radiotelephone according to the present invention.

4 is a circuit diagram according to the present invention.

5 is a flowchart illustrating the operation of the microcomputer 50 of FIG.

* Explanation of symbols for main parts of the drawings

Q1-Q3: 1-3 Transistor D: Diode

R1-R4: Resistor SW1: Power switch

SW2: Mode selector switch 40: Storage battery

50: micom

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a remote unit (hand set) in a wireless telephone, and more particularly to a circuit for controlling power supply to a transmission and reception module during charging.

Typically, the radiotelephone is connected to the telephone line of the switch, as shown in FIG. The main body 100 that propagates through and modulates a voice signal into a signal of a predetermined frequency band to propagate through the antenna 220 and receives a signal of a predetermined frequency generated from the main body 100 through the antenna 220. At the same time, a remote having a dial keypad 210 or the like as demodulated is constituted by one set.

Such a cordless telephone has a function of making a call using a telephone line without a line code, as is well known. The conventional remote 200 has power input terminals 1 and 2 corresponding to the power supply terminals 1 'and 2' which are located on the upper surface of the main body 100 during the first middle and output a predetermined level of power. It has a power supply circuit for charging a voltage to the internal capacitor when the remote 200 is placed on the main body 100. The power supply circuit in the remote 200 inputs and charges power through the power input terminals 1 and 2 to supply operating voltages to respective parts of the internal circuits during communication and standby.

The circuit of the conventional remote 200 as described above includes a transmitting module 10 for modulating an input voice signal into a signal of an input predetermined frequency and a receiving module for demodulating the modulated signal of a predetermined frequency into an input voice signal as shown in FIG. 20) and a signal of a predetermined frequency output from the transmitting module 10 through the antenna 220, and a signal of a predetermined frequency received through the antenna 220 to the receiving module 20 A transmission / reception filter 30 to be transmitted, a first power input terminal 1 for inputting a first power supply Vcc supplied from the first power supply terminal 1 'on the main body 100, and the first Inputting the diode D for one-way transmission of the first power source Vcc of the power source input terminal 1 and the second power source GND supplied from the second power supply terminal 2 'on the main body 100. A second power input terminal 2 for connection between the second power input terminal 2 and the diode D; Is accumulated through the line 4 and discharges the storage voltage through the line 4 when the output of the diode D is interrupted, and the output power of the storage battery 40 and the diode D. The operator is connected between the power switch (SW1) for switching the voltage, the power switch (SW1) and the receiving module 20 and the transmission module 10, the power supplied through the power switch (SW1) According to the selected mode, it is composed of a supply power control switch (SW2) to supply only to the reception module 20 or to the transmission and reception modules (10, 20), respectively.

In the above configuration, the supply power control switch SW2 is a mode control switch for selecting a standby mode and a call mode. In the standby mode, the power supply control switch SW2 supplies input power to the new module 20, and in the call mode. Supply power to both the transmission and reception modules 10 and 20.

First, when charging, the remote 200 is placed on the main body 100. At this time, the first power input terminal 1 and the second power input terminal 2 are connected to the first power supply terminal 1 ′ of the main body 100. ) And a first power source (Vcc) and a second power source (GND) output from the second power supply terminal (2 '), respectively. In this case, the diode D transmits the first power Vcc applied through the first power input terminal 1 as a general-purpose diode to the storage battery 40 through the line 4. Therefore, the storage battery 40 accumulates the difference voltage between the first power input terminal 1 and the second power input terminal 2. In addition, when discharging, the remote 200 is separated from the main body 100. When the power switching switch SW1 is turned on by the user, the power supply switch SW2 is stored in accordance with the mode selected by the input operator. The accumulated power of the 40 is supplied to the water transmitting and receiving modules 10 and 20. In the standby mode, the accumulated voltage of the storage battery 40 input through the power switching switch SW1 only to the receiving module 20. Supplies and supplies to both the transmission and reception modules 10 and 20 in the call mode.

The power circuit of the conventional remote 200 that is operated as described above is the first power source when the power is switched on the main body 100 in the state in which the power switch (SW1) is turned on (call standby mode or call mode) The first power supply Vcc of the main body 100 supplied through the input terminal 1 and the diode D is connected to the transmission module through the storage battery 40, the power switch, and the power supply control switch SW2. 10) or the power supplied to the receiving module 20 in parallel and accumulates in the storage battery 40 is reduced and the charging time is long.

Accordingly, an object of the present invention is to provide a transmission and reception power cut-off circuit during charging of a radiotelephone that can be rapidly charged by cutting off the power supply provided to each part when the remote and the main body are combined to charge the power.

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

3 is a configuration diagram of a wireless telephone according to the present invention, next to the first and second power supply terminals 1 'and 2' and the second power supply terminal 2 'in the main body 100 of the first diagram. Main body 100 to which charging display terminal 3 'for transmitting charge display signal in a predetermined logic state is added, first and second power supply terminals 1' and 2 'of the main body 100, and charging. And a remote 200 having first and second power input terminals 1 and 2 and a charge display input terminal 3 corresponding to the display terminal 3 '.

At this time, the charge display signal output from the charge display terminal 3 'is a logic of the power supply voltage Vcc level output from the first power supply terminal 1' with logic of a predetermined state.

4 is a detailed circuit according to the present invention, a transmission module 10 for modulating a voice signal into a signal of a predetermined frequency, a receiving module 20 for demodulating a signal of a predetermined frequency into a voice signal, and the transmission module 10. And a separate transmission / reception filter 30 for propagating a signal of a predetermined frequency of through the antenna 220 and transmitting a signal of a predetermined frequency propagating through the antenna 220 to the receiving module 10 and the main body ( First power input terminal 1 for inputting the first power supply Vcc supplied through the first power supply terminal 1 'on 100, and second power supply terminal 2' on the main body 100. The second input terminal 2 for inputting the second power supply GND supplied through the second display terminal, and the charge display input terminal for inputting the charge display signal applied through the charge display terminal 3 'on the main body 100. (3), a diode D for outputting the first power source Vcc of the first power source input terminal 1 in one direction, and the second power source input terminal 2; And a storage battery (40) connected between the diode (D) and the first power source of the diode (D) via a line (4). The microcomputer 50 for controlling the power supply of the system, the power switch (SW1) for controlling the transmission of the accumulated power of the battery 40 to the transmission and reception module, and the standby and call mode selected by the operator And a mode selection switch SW2 for switching the mode selection signal to the second input terminal I2 of the microcomputer 50 and a logic state of the charging display input terminal 3 as a base. When charging and discharging by connecting or disconnecting the first input terminal I1 of the microcomputer 50 connected to the collector with the second power source GND by performing ON-OFF switching operation according to the logic state. The power supply by performing an on-off operation according to a first transistor Q1 for detecting a signal and a first control signal applied from the first control terminal O1 of the microcomputer 50 to the base through a resistor R2. Output power at the time of power storage 40 supplied through the opening and closing switch (SW1) According to the second transistor (Q2) to transmit or block to the receiving module 20, and the second control signal applied to the base through the resistor (R4) from the second control terminal (O2) of the microcomputer (50) The third transistor Q3 transmits or blocks power on the collector of the second transistor Q2 to the transmitting module through an emitter-collector by performing an on-off switching operation.

FIG. 5 is a flowchart illustrating the operation of the microcomputer 50 shown in FIG. 4. The input logic state of the first input terminal 11 and the second input terminal I2 is searched at predetermined intervals to detect the first control terminal O1 and the first control terminal O1. It shows the output of a signal for switching the power supply control to the second control terminal (O2).

An operation example of the present invention will be described in detail with reference to FIGS. 3, 4, and 5.

3 illustrates that when the remote 200 is placed on the main body 100 during charging, the first and second power supply terminals 1 ′ and 2 ′ and the charging display terminal 3 ′ of the main body 100 are connected to the remote 200. Are connected to the first and second power supply input terminals 1 and 2 and the charge display input terminal 3, respectively. Therefore, the remote 200 accumulates a voltage corresponding to the difference between the first power source Vcc and the second power source GND supplied from the main body 100. At this time, the remote 200 is supplied only to the storage battery 40 embedded therein by the charging display signal of a predetermined logic state inputted to the charging display input terminal 3 'connected to the charging display terminal 3' of the main body 100. Power is accumulated, and the main body 100 generates a ring signal by operating a ring when the call signal is humanized from the counterpart station. In addition, when discharged, i.e., in standby or call mode, the remote 200 is separated from the main body 100 and receives a signal of a predetermined frequency propagated from the main body 100 to generate a voice signal and converts the voice signal to a predetermined frequency. Modulates and propagates the signal.

FIG. 4 is a diagram illustrating the first and second power input terminals 1 and 2 that are applied to the first and second power input terminals 1 and 2 during charging, that is, when the remote 200 is placed on the main body 100 regardless of the on / off state of the power switch. The voltage difference between the first power source Vcc and the second power source GND is charged in the storage battery 40 and cuts off the power supply of the transmission / reception module 10, 20. The power supply of the transmission / reception module 10, 20 is performed. Blocking of is performed by the following operation. When the remote 200 is mounted on the main body 100 as described above, a charge display signal of a high logic state output from the charge display terminal 3 'on the main body 100 is applied to the charge display input terminal 3, The first power source Vcc and the second power source GND are supplied to the first and second power source input terminals 1 and 2.

Accordingly, the die mode D buffers the first power supplied through the first power input terminal 1 to switch the microcomputer 50, the battery 40, the resistors R1, R3, and the power switch through the line 4. To the switch SW1.

At this time, the first transistor Q1 is switched on by inputting a charge display signal of a "high" logic state inputted to the charge display input terminal 3 as a base. That is, when the charge display signal of the logic state through the charge display input terminal 3 is input to the base, the first transistor Q1 is " on " Turn on. Accordingly, the first input terminal of the microcomputer 50 is bypassed by bypassing the first power supply Vcc on the line 4 supplied through the resistor R1 between the collector and the emitter of the first transistor Q1. I1) is supplied with a charge detection signal in a low logic state.

The microcomputer 50 operated as shown in FIG. 5 while operating as described above detects whether logic “high” is output to the first input terminal I1 in step 510. When the microcomputer 50 searches in step 510, a charge detection signal having a “low” logic state supplied from the collector of the first transistor Q1 is input to the first input terminal I1 of the microcomputer 50. When the microcomputer 50 determines that the remote 200 is mounted on the main body 100, the microcomputer 50 receives the first and second control signals of the “high” logic state in steps 512 and 514. Output to (O1, O2).

Therefore, the second transistor Q2 and the third transistor Q3 are turned off by the first and second control signals in the high logic state applied to their respective bases, thereby turning off the emitter and the collector. The supply of the first power Vcc input through the open / close switch SW1 is cut off. Therefore, the first power supply Vcc output to the first power supply terminal 1 ′ of the main body 100 and supplied to the first power input terminal 1 is accumulated in the storage battery 40 through the diode D.

On the other hand, when the remote 200 is discharged from the main body 100, the first and second power supply terminals 1 and 2 of the remote 200 and the charge display input terminal 3 have a first power source Vcc and The second power source GND and the charge display signal are not applied. Accordingly, the first and second power supply terminals 1 and 2 and the charge display input terminal 3 both maintain a "low" logic state. In this state, the battery 40 supplies the stored power to the line 4. It supplies to the microcomputer 50 and the power switch (SW1) and the resistors (R1, R3) through.

When the remote 200 is separated from the main body 100 as described above, no signal is input to the charge display input terminal 3. Therefore, the bias is not applied between the base and the emitter of the first transistor Q1 and is turned off. Therefore, the voltage of the storage battery 40 applied through the resistor R1 is applied to the first input terminal I1 of the microcomputer 50. At this time, the microcomputer 50 performing the operation as shown in FIG. 5 determines if the logic is “high” as the first input terminal I1 in step 510 (the remote 200 is separated from the main body 100). In the process, it is searched whether the second input terminal I2 is "high".

If the input of the second input terminal I2 is low in step 516, the microcomputer 50 determines that the standby mode is in the standby mode (SW2 is in an off state) and the first input terminal I1 is turned off by the first transistor Q1. In step 522, the first control signal in the low logic state is output to the first control terminal O1 by the high logic state of the signal, and in step 524, the second control signal in the high logic state is output to the second control terminal O2. . Accordingly, the second transistor Q2 and the third transistor Q3 are “low” and “high” signals output from the first control terminal O1 and the second control terminal O2 of the microcomputer 50 respectively. On "and" off "are the standby mode in which power through the power opening / closing switch SW1 is applied only to the receiving module.

On the other hand, when the mode selection switch SW2 is turned on by the user's selection and is in the call mode from the standby mode, the voltage of the resistor R3 flows through the switch SW2, thereby providing logic to the second input terminal I2. "Low" is entered.

If the second input terminal I2 is “low”, the microcomputer 50 detects it at step 516, and at step 516, the microcomputer 50 determines that the second input terminal I2 is “low”. In steps 518 and 520, the first and second control signals in a low logic state are output to the first control terminal O1 and the second control terminal O2, respectively.

As described above, when the microcomputer 50 outputs the first and second control signals having the "low" level, the second transistor Q2 is turned on by the first control signal in the low logic state, and the power switch SW1 is turned on. The power supply of the battery 40 applied to the emitter is supplied to the emitter of the receiving module 20 and the third transistor Q3 through the line 5 connected to the collector. The third transistor Q3 is " on " by the second control signal in a low state, so that power supplied from the second transistor Q2 through the line 5 is transmitted through the emitter collector. ). Therefore, when the remote 200 is separated from the main body 100 and the first transistor Q1 is turned off, the microcomputer 50 always outputs a "low" signal to the first control terminal O1 to the receiving module 20. The power supply voltage is supplied, and a low / high signal is output to the second control terminal O2 according to the on / off of the mode selection switch SW2 to supply or cut off power to the transmission module 10.

In the present invention, a power switching element is used as a transistor, but a person skilled in the art has a function of the first transistor Q1-Q3 and has a field effect transistor (FET) or other control terminal. You will know that it can be implemented with switches.

As described above, the present invention has the advantage of preventing unnecessary power loss during charging and shortening the charging time, and can also control the power supply of the transmission and reception modules 10 and 20 by the microcomputer 50 during standby or call mode. There is an advantage to that.

Claims (1)

A transmission module 10 for modulating a voice signal into a voice signal of an input predetermined frequency, a reception module 20 for demodulating a signal of a predetermined frequency into an input voice signal, and a signal of a predetermined frequency of the transmission module 10 In the remote of the radio telephone having a transmission and reception separation filter 30 for transmitting a signal of a predetermined frequency propagated through the 220, and propagated through the antenna 220 to the receiving module 20, to the main body First power input terminal 1 for inputting the first power source Vcc to the second power source, second power input terminal 1 for inputting the second power source GND from the main body, and the first and second Connection between power input terminals 1 and 2 A storage battery 40 for accumulating the difference voltage between the first power supply and the second power supply, and a connection between the storage battery 40 and the first power input terminal. Diode (D) for transmitting to the capacitor 40, and maintains the on-off operation state according to the operator's operation A power switch SW1 which transmits or cuts off the first power supplied through the accumulated power of the storage battery 40 or the diode D to the transmission / reception modules 10 and 20, and a microcomputer for controlling the system. 50), a charge display input terminal 3 for inputting a charge display signal in an arbitrary logic state from the main body, and a charge display input terminal 3 connected to the charge display input terminal 3; An inverter circuit comprising a resistor R1 and a first transistor Q1 for detecting whether a signal is applied and outputting a charge detection signal having a logic opposite to that of the charge display signal to a first input terminal of the microcomputer 50; A mode selection switch SW2 for generating a mode selection signal in an arbitrary logic state by the operator's selection and outputting it to the second input terminal I2 of the microcomputer 50, the power switching switch SW1, and the transmission / reception module Connected between 10 and 20 A second transistor Q2 and a resistor R2 for controlling the power supplied to the transmission / reception modules 10 and 20 through the power switching switch SW1 according to the first control signal of the microcomputer 50. The switching module 10 is connected between the second transistor Q2 and the transmission module 10 to supply power applied through the second transistor Q2 by the second control signal of the microcomputer 50 to the transmission module 10. A second switching circuit composed of a third transistor Q3 and a resistor R4 for controlling the transmission to the transmitter), the charging / receiving module 10 20) Power supply circuit for transmitting and receiving during charging of a wireless telephone, characterized in that the power supply to cut off.

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