KR950007497B1 - The communications between handsets of digital celluar phone - Google Patents

Abstract

For the digital cordless telephone, the method provides a base unit circuit offering communication function between handsets. The base unit block of digital cordless telephone consists of the first handset(HS1), the second handset(HS2), a micom(100), an antenna(101), a power distributor/mixer(102), the first option block(110), the second option block(121), a signal transformer(125) and a line interface(126).

Description

Communication circuit and method between handset and digital handset

1 is a block diagram of a base unit of a digital radiotelephone according to the present invention.

2 is an operation flowchart of a base unit of a digital radiotelephone according to the present invention.

3 is a flowchart of operation of the first handset according to the present invention.

4 is an operation flowchart of a second handset according to the present invention.

* Explanation of symbols for main parts of the drawings

100: micom 101: antenna

102: power divider / synthesizer RF1: first high frequency part

RF2: second high frequency unit 109: first data and clock extraction unit

120: second data and clock extraction unit 110: first selection unit

121: second selection unit 125: signal conversion unit

126: line interface unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a handset and a base unit of a digital radiotelephone having multiple handsets, and more particularly, to a base unit circuit and a communication method for enabling communication between handsets.

In general, in a digital wireless telephone with multiple handsets, the base unit has only one channel frequency for communication between the handset and the base unit. Therefore, only one handset can communicate with the base unit even when communicating with the multiple handsets. Only communication between handsets and handsets is currently impossible. However, this is often inconvenient at times and users want to solve this inconvenience.

It is therefore an object of the present invention to provide a base unit circuit which enables communication between a handset and a handset in a digital radiotelephone.

Another object of the present invention is to provide a method for enabling communication between a handset and a handset in a digital radiotelephone.

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

1 is a block diagram of a base unit of a digital radiotelephone according to the present invention, the base unit circuit including at least a first handset HS1 and a second handset HS2; A microcomputer 100 for performing various kinds of control required when the first handset HS1 and the second handset HS2 communicate with each other, and various kinds of control required when the user communicates with a subscriber through a public switched network; An antenna 101 for transmitting and receiving radio waves with the first handset HS1 and the second handset HS2; It has a common port (A) connected to the antenna 101, the first branch (B) and the second branch (C), when receiving a signal from the antenna 101 to the common port (A) of the signal Uniformly distributes power to transfer to the first branch (B) and the second branch (C), and evenly combines the power of the signals supplied to the first branch (B) and the second branch (C) to a common port ( A power divider / synthesizer 102 for transmitting to A); Under the control of the microcomputer 100, a predetermined first transmission data is received, modulated, amplified and transmitted to the first branch B of the power splitter / synthesizer 102, and the first branch of the power splitter / synthesizer 102 is used. A first high frequency unit RF1 for demodulating and outputting received data from (B); A first data and clock extracting unit 109 for extracting data and a clock from a signal demodulated by the first high frequency unit RF1 under the control of the microcomputer 100; According to the control of the microcomputer 100, the second branch data C of the power splitter / synthesizer 102 is modulated and supplied to the second branch C, and the second branch C of the power splitter / synthesizer 102 is supplied. A second high frequency part (RF2) for demodulating and outputting the received data of the apparatus; A second data and clock extracting unit 120 for extracting data and a clock from a signal demodulated by the second high frequency unit RF2 under the control of the microcomputer 100; A line interface unit 126 for interfacing with a public telephone network; Under the control of the microcomputer 100, the analog signal flowing from the public telephone network through the line interface unit 126 is converted into a digital signal and outputted, and the data from the first and second data and the clock extraction unit 109 and 120 are clocked. A signal converter 125 for converting an analog signal into a public telephone network through the line interface 126; Under the control of the microcomputer 100, the digital signal output from the signal converter 125 or the second data and the signal output from the clock extractor 120 are selected and transmitted to the first high frequency part RF1. A first selector 110 for outputting as data; Under the control of the microcomputer 100, a digital signal output from the signal converter 125 or a signal output from the first data and clock extractor 109 is selected to transmit a second signal to the second high frequency part RF2. It consists of a 2nd selection part 121 which outputs as data.

The power divider / synthesizer 102 is known in the art as described on page 383 of the book Microwave Engineering, published in 1990 by Addison-Wesley Publishing Company, Inc. The first high frequency part RF1 and the second high frequency part RF2 are also known technologies, and thus, detailed descriptions of their internal configuration and operation will be omitted.

2 is an operation flowchart of the base unit according to the present invention, in which the first handset HS1 enables communication between the second handset HS2.

Referring to FIG. 2, a communication method between the first handset HS1 and the second handset HS2 may include; An intercom signal generation determining step of determining whether an intercom signal to communicate with the second handset HS2 is generated from the first handset HS1; A channel frequency generation process of generating a channel frequency of the second handset HS2 and transmitting it to the second handset HS2 when an intercom signal to communicate with the second handset HS2 is generated from the first handset HS1; ; A response data analysis process of analyzing response data from the second handset (HS2) generated in response to the transmitted channel frequency; Forming a passage between the first handset HS1 and the second handset HS2 when the response data indicates that the second handset HS2 can pass; When the response data from the second handset HS2 indicates that the second handset HS2 cannot pass the predetermined number of times, the first handset HS1 receives a status signal indicating that the call with the second handset HS2 is impossible. It consists of sending out the call impossible status signal.

FIG. 3 is a flowchart of operation of the first handset HS1, and FIG. 4 is a flowchart of operation of the second degree handset HS2. At this time, since the processing operation is performed in the same manner as the operation performed in the existing handset, even if the processing operation accordingly is not described in detail, it is a known technique that can be understood by those skilled in the art.

1 to 4, the base unit circuit of the present invention enables the communication between the handset and the handset in detail.

First, the principle of the present invention will be briefly described. The present invention provides a method in which the base station and the handset are time-divisionally communicated with one frequency of two-way communication between the base unit and the base station when the multi-handset is applied in a home or office. By having two transmit and receive frequency channels in the unit, communication between handsets is possible.

The base unit for realizing the principle of the present invention as described above is configured as shown in FIG. 1, the operation is performed through the flow shown in FIG.

Referring to FIG. 1, an analog voice signal of a caller received through the line interface unit 126 is first converted into digital data by the control of the microcomputer 100 in the signal converter 125. The digital data is input to the first selector 110, converted into a final transmission ratio under the control of the microcomputer 100, and then selected and input to the first high frequency unit RF1. The output signal of the first selector 110 is modulated and amplified by the first high frequency unit RF1 under the control of the microcomputer 100, and then, through the power splitter / synthesizer 102 and the antenna 101, the first handset ( HS1).

At this time, when the first handset HS1 responds, the response signal is applied to the first high frequency part RF1 through the antenna unit 101 of the base unit and the power divider / synthesizer 102 and demodulated, and then the first data and clock are received. It is input to the extraction part 109. The first data and clock extractor 109 extracts clock and data from a signal demodulated by the first high frequency unit RF1 under the control of the microcomputer 100. The extracted clock and data are converted into an analog signal by the signal converter 125 controlled by the microcomputer 100 and then transmitted to the passer through the line interface 126.

In this state, in order for the first handset HS1 to intercom with the second handset HS2, the microcomputer 100 requests that the first handset HS1 intercom with the second handset HS2 in the signal converter 125. The call is interrupted for a moment between the caller and the first handset HS1 and the intercom signal of the first handset HS1 is applied to the second high frequency part RF2 via the second selector 121. Then, according to the control of the microcomputer 100, the second handset HS2 modulates the frequency allocated to the second handset HS2 different from the frequency modulated by the first high frequency unit RF1, and then the power divider / synthesizer 102 And through the antenna 101 to the second handset HS2.

At this time, if the second handset HS2 is passable, the second handset HS2 sends a message to the base unit indicating that it is possible to talk to the first handset HS1. Then, the second high frequency part RF2 of the base unit demodulates the signal of the second handset HS2 received through the antenna 101 and the power divider / synthesizer 102 to the second data and clock extracting part 120. Is approved. The second data and clock extractor 120 extracts the data and the clock from the output signal of the second high frequency unit RF2 and inputs them to the signal converter 125. The microcomputer 100 converts the signal according to the extracted clock. The data converted in section 125 is read to recognize that the second handset HS2 can communicate with the first handset HS1.

If the second handset HS2 is able to communicate with the first handset HS1, the microcomputer 100 simultaneously transmits the intercom signal to the first handset HS1 and the second handset HS2, and the first handset HS1. ) Is transmitted to the second selector 121 through the power divider / synthesizer 102, the first high frequency unit RF1, the first data and the clock extractor 109. Then, the second high frequency part RF2 modulates the output signal of the second selector 121 and transmits the information to the second handset HS2 via the power divider / synthesizer 102 and the antenna 101. In addition, the microcomputer 100 receives the signal of the second handset HS2 through the antenna 101, the power divider / synthesizer 102, the second high frequency unit RF2, the second data, and the clock extractor 120. To be transmitted to the selection unit 110. Then, the first high frequency part RF1 modulates the output signal of the first selector 110 and transmits the information to the first handset HS1 through the power divider / synthesizer 102 and the antenna 101.

In the above description, the first high frequency part RF1 and the second high frequency part RF2 will be briefly described for better understanding of the known technology or the present invention.

The first high frequency unit RF1 and the second high frequency unit RF2 have the same configuration, and the first and second switching units 10 and 20 may transmit signals on the same line during transmission and reception. And amplified by two receiving amplifiers (11, 21). The first and second synthesizers 12 and 22 generate two local oscillation frequencies, a reception local oscillation frequency and a transmission local oscillation frequency, under the control of the microcomputer 100. The first and second mixers 13 and 23 generate and output an intermediate frequency by mixing the reception local oscillation frequencies output from the first and second synthesizers 12 and the outputs of the first and second reception amplifiers 11 and 21. . The generated intermediate frequency passes through the first and second band pass filters 14 and 24 to remove noise, and the signal from which the noise is removed is demodulated by the first and second demodulators 15 and 25.

In addition, the first and second transmission data input from the first and second selectors 110 and 121 are modulated by the first and second modulators 16 and 26. The third and fourth mixers 17 and 27 mix and output the first and second transmitting local oscillation frequencies output from the first and second synthesizers 12 and 22 and the signals from the first and second modulators 16 and 26. The first and second transmit amplifiers 18 and 28 amplify the signals from the mixers 17 and 27 and then output them through the first and second switching units 10 and 20.

As described above, when the base unit operates, the operation of the first handset HS1 is performed through the flow shown in FIG. 3. First, it is determined whether the first handset HS1 requires intercom with the second handset HS2. Recognize in step 301. In this case, if it is determined that there is an intercom request, a transmission channel frequency is generated in step 302, and an intercom signal with the second handset HS2 is loaded on the frequency in step 303 and transmitted to the base unit. At this time, if there is a response from the base unit, the controller starts passing through the second handset HS2 in step 304. If there is no response, steps 306 and 307 are repeatedly performed, and then the first handset HS1 Sends an error signal on the mounted speaker.

Operation of the base unit for the call of the first handset (HS1) and the second handset (HS2) is performed through the same flow as in FIG. 2, which requires intercom with the second handset (HS2) from the first handset (HS1). When the signal is received, the microcomputer 100 recognizes it in step 201 and determines the transmission frequency to call the second handset HS2 in steps 202 and 203, and then the first handset HS1 at the determined transmission frequency. ) And the intercom signal is transmitted to the second handset HS2. In this case, when the call enable signal is transmitted from the second handset HS2, the microcomputer 100 determines this in step 204. In step 205, the microcomputer 100 determines a call path between the first handset HS1 and the second handset HS2. To make calls with each other.

However, if the second handset HS2 is in a call state and cannot pass through with the first handset HS1, the microcomputer 100 repeats steps 202 and 203 to check whether the call ends. In operation 207, the first handset HS1 determines that the call is impossible with the second handset HS2, and transmits a call disablement signal to the first handset HS1 and ends.

On the other hand, the operation of the second handset (HS2) is performed according to the flow as shown in Figure 4, when receiving the pass request signal of the first handset (HS1) from the base unit to recognize it in step (401), When not in a call, the channel frequency is generated in step 402 and the information indicating that the call is possible is transmitted to the base unit so that the call is possible with the first handset HS1 in step 403.

The implementation of the base unit circuit operating as described above has the advantage of enabling communication between the handset and the handset when operating a wireless telephone having multiple handsets in a home or an office. Accordingly, the user can conveniently talk not only through a public telephone network but also through another handset.

Claims (3)

A base unit circuit of a digital radiotelephone comprising a first handset HS1 and a second handset HS2; Control means for performing various controls required when the first handset HS1 and the second handset HS2 communicate with each other, and various controls required when the user communicates with a subscriber through a public switched network by handset; An antenna configured to transmit and receive radio waves with the first handset HS1 and the second handset HS2; It has a common port (A), a first branch (B) and a second branch (C) connected to the antenna, the uniform power of the signal when receiving the signal from the antenna to the common port (A) The first branch B and the second branch C are distributed to each other, and the powers of the signals supplied to the first branch B and the second branch C are equally coupled to the common branch. Power distribution / synthesis means for transmitting to the port A; Under the control of the control means, a predetermined first transmission data is received, modulated, amplified and transmitted to the first branch B of the power distribution / synthesis means, and the first branch B of the power distribution / synthesis means. First high frequency processing means for demodulating and outputting received data from the apparatus; First data and clock extracting means for extracting data and a clock from a signal demodulated by the first high frequency processing means under control of the control means; Under the control of the control means, a predetermined second transmission data is modulated and supplied to the second branch C of the power distribution / synthesis means, and the reception data from the second branch C of the power distribution / synthesis means is provided. Second high frequency processing means for modulating and outputting the modulated signal; Second data and clock extraction means for extracting data and a clock from a signal demodulated by the second high frequency processing means under control of the control means; Interfacing means for interfacing with a public telephone network; Under the control of the control means, an analog signal flowing from the public telephone network through the interfacing means is converted into a digital signal and outputted, and the data from the first and second data and the clock extraction means is converted into an analog signal according to a clock. Signal conversion means for outputting to the public telephone network through the interfacing means; Selecting a digital signal output from the signal conversion means or selecting a signal output from the second data and the clock extraction means according to the control of the control means and outputting the first signal to the first high frequency processing means as the first transmission data; First selection means; Selecting a digital signal output from the signal conversion means or a signal output from the first data and clock extraction means and outputting the second signal to the second high frequency processing means as the second transmission data according to the control of the control means; A communication circuit between the handset and the handset, characterized by comprising two selection means. A communication method between the first handset (HS1) and the second handset (HS2) in a base unit of a digital radio telephone including at least a first handset (HS1) and a second handset (HS2); An intercom signal generation determining step of determining whether an intercom signal to communicate with the second handset HS2 is generated from the first handset HS1; When an intercom signal to communicate with the second handset HS2 is generated from the first handset HS1, a channel for generating a channel frequency of the second handset HS2 and transmitting the same to the second handset HS2. Frequency generation process; A response data analysis process of analyzing response data from the second handset (HS2) generated in response to the transmitted channel frequency; When the response data indicates that the second handset (HS2) can pass, it comprises a process of forming a call path to form a communication path between the first handset (HS1) and the second handset (HS2). The communication method between the handset and the handset. According to claim 2, When the response data from the second handset (HS2) indicates that the second handset (HS2) is impossible to pass a predetermined number of times, the call of the second handset (HS2) is impossible. The communication method between the handset and the handset further comprises the step of transmitting a non-call state signal to transmit the status signal to the first handset (HS1).

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