KR950002580B1 - Keyphone system - Google Patents

Abstract

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Description

Data transmission and reception device of key phone system

1 is a block diagram of a conventional key-phone system data transceiver.

2 is a block diagram of a device for data transmission and reception of a key phone system according to the present invention.

3 is a detailed equivalent circuit diagram of a key phone system data transmission and reception device according to FIG.

4 is a time waveform diagram of input and output signals according to the ASK modulator according to FIG. 3;

5 is a time waveform diagram of an input / output signal according to a receiver according to FIG.

* Explanation of symbols for main parts of the drawings

1, 10: serial-parallel receiver 2: voice band modem

3, 30: hybrid circuit 20: ASK modulator

40 receiver 41 amplifier

42: comparator 43: monostable multivibrator circuit

T: Transformer U1: Monostable Multivibrator

U2: comparator U3, U4: op amp

U5: OR gate U6: NOR gate

U7: Inverter R1, R2, R3, R4, R5, R6, R7, R8: Resistance

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data transmission / reception apparatus of a key phone system, and more particularly, to a data transmission / reception apparatus for data communication in a ping-pong method using pulses for exchanging data between a main body and a subscriber-only telephone period.

In general, a key phone system is a voice exchange device that allows one or two or more curved lines to be shared and used by a large number of subscribers. It is mainly composed of a key service unit (KSU) and a subscriber telephone (KTS). .

The key phone system requires a main body and a subscribing voice channel for a voice call, a data channel for data transmission and reception, and a power channel for supplying power for driving a subscriber-only telephone in the main body. The 6-wire system, which allocates 2 wires to each channel of voice, data and power and connects the subscriber telephone to the main body and 6 wires, is uneconomical due to the large number of lines.

수신데이타가 일그러짐 없이 안정하게 전송될 수 있다. 이러한 송

수신되는 2진 데이타의 직류 성분을 없애기 위해서는 AMI(Alternate Mark Inversion), 바이페이스(Biphase)등의 특수한 코드를 사용하거나 음성 대역의 모뎀을 사용한다. 특수한 코드를 사용하는 4선식은 동기식 전송이어야 하므로 복잡한 하드웨어를 필요로 한다.In addition, the two-wire type that transmits data and power to one channel including data and power to the voice channel combines voice, data, and power in two lines, and has a high performance filter for separating voice and data, and a volume for separating power. Because of the need for a large transformer and a separate coil, it is expensive and bulky, so it is rarely used. For this reason, the four-wire type is most commonly used for powering audio signals and data using an intermediate tap of a transformer using independent channels. Since this 4-wire system uses a coupling transformer (coupling transformer) for the data channel, the transmission carrier signal must be free from direct current.

Receive data can be transmitted stably without distortion. Such a song

In order to remove the DC component of the received binary data, a special code such as Alternate Mark Inversion (AMI), Biphase or a modem in a voice band is used. Four-wire using special code requires synchronous transmission and therefore requires complex hardware.

As shown in FIG. 1, a four-wire system using a modem in a voice band is transmitted in series through a data bus from a microprocessor at a serial parallel receiver (UART). The transmission data (Tx DATA) is input to the voice band modem 2, converted into a transmission carrier signal (Tx Carrier), and then output to the hybrid circuit 3 to transmit the transmission signal to the receiver. The hybrid circuit 3 is directly connected to the secondary side of the coupling transformer (coupling transformer: T), and the reception carrier (Rx Carrier), which is a reception signal transmitted to the hybrid circuit 3, is transferred to the voice band modem 2. It is output and transmitted to UART (1) as RX DATA.

However, the four-wire type using the voice band modem has the disadvantage of using expensive modems and complicated peripheral circuits.

In order to overcome the above problems, the data transmission / reception apparatus of the four-wire keyphone system according to the present invention supplies power by using an intermediate tap of a transformer, and transmits data rate in order to eliminate direct current component and reduce band frequency in the transmission carrier. It is an object of the present invention to provide an apparatus for transmitting and receiving data between a main body and a subscriber-only telephone period by using a carrier signal having the same frequency.

In order to achieve the above object, serial and serial transmission and reception of the data transmitted in parallel from the microprocessor, serially transmitted signals to the microprocessor in parallel, and interface to send the transmission ready signal to the receiver Wealth and; An ASK modulation unit for carrying a carrier frequency of one cycle in binary data transmitted from the serial-parallel transceiver unit with one bit of "0" data; A hybrid circuit which transmits the transmission carrier signal outputted from the ASK modulator, separates the transmission signal mixed with the reception signal transmitted from the receiver, and transmits the reception carrier signal; And a receiver for receiving a signal transmitted from the hybrid circuit and generating a pulse to transmit the received data to the serial and parallel receiver.

Hereinafter, a data transmission and reception apparatus of a key phone system according to the present invention will be described with reference to the accompanying drawings.

Referring to FIG. 3, the data transmitting / receiving apparatus of the key phone system according to the present invention includes a serial / parallel receiver 10, an ASK modulator 20, a hybrid circuit 30, and a receiver 40. As shown in FIG.

The ASK modulator 20 includes an OR gate U5 for inputting a transmission data signal TxD and a transmission clock signal CLK output from the serial-parallel receiver 10 and outputting the data according to a logical combination value; An inverter (U7) for inverting and outputting the transmission clock signal; And a NOR gate U6 for inputting the transmission data and the output of the inverter and outputting the output according to a logical combination value. The hybrid circuit 30 adds and amplifies the output signal of the ASK converter 20. Each end of the two predetermined resistors R7 and R8 is connected in series with the output terminals of the OR gate U5 and the NOR gate U6, and the feedback resistor R6 to which the other ends of the resistors R7 and R8 are connected. An inverting op amp U4 having; The primary side is a coupling transformer T which is connected to the data line and the secondary side is connected to a predetermined resistor R5 and the receiver 40.

In addition, the receiver 40 includes: an amplifier 41 which is an inverted OP amplifier U3 having a predetermined feedback resistor R4 for amplifying the output signal of the hybrid circuit 30; A comparator 42 for generating a drive signal of the monostable multivibrator U1 in comparison with the output signal of the amplifier 41 and the reference voltage Vref; The output signal of the comparator 42 is supplied with a predetermined driving voltage, connected to a predetermined resistor R3 and pulled up to be supplied to the inverting input terminal B of the OR gate inside the multivibrator U1. The driving voltage of is input to the input terminal (A) of the OR gate through a predetermined resistor (R2), the output signal of the OR gate is input to the trigger terminal, the driving voltage is connected to the T2 terminal through the resistor (R1) The capacitor grounded at one end includes a monostable multivibrator circuit 43 connected to the T1 terminal to have a constant time constant.

The operation of the data transceiver of the key phone system according to the present invention will be described with reference to FIGS. 3, 4 and 5.

이 인가되어 상기 ASK변조부(20)의 출력신호를 증폭한다. 이때, 각부의 입출력신호는 제4도에 도시된 바와 같다. 여기에서, (a)는 UART(10)에서 출력되는 송신클럭신호(CLK)의 파형이고 (b)는 UART(10)에서 출력되는 송신데이타(TxD)의 파형이다. (c)는 OR게이트(U5)의 출력파형이고 (d)는 NOR게이트(U6)의 출력파형이다. (e)는 OP앰프(U4)에서 출력되는 파형으로써 상기 OR게이트(U5)의 출력 및 NOR게이트(U6)의 출력의 합에 해당하고 이 파형은 ASK변조된 것으로 항상 직류성분이 없으므로 변압기(T)를 통하여 멀리까지 전송할 수 있다. 상기 ASK 변조부(20)에서 출력되는 변조된 신호는 1비트(Bit)의 "0"인 데이타에 1주기의 캐리어 주파수를 실어 보내므로 이 캐리어의 대역폭이 전송하고자하는 데이타의 대역폭과 같게 된다.In the serial / parallel transmitter / receiver 10 that transmits the parallel signal transmitted from the microprocessor in series, the transmission data TxD is output to one input terminal of the OR gate U5 and the NOR gate U6 of the ASK modulator 20. The transmission clock signal CLK is output to the OR gate U5 and the inverter U7, and the output signal of the inverter U7 is supplied to the type force terminal of the NOR gate U6. If the two resistors R7 and R8 connected to the output terminals of the OR gate U5 and the NOR gate U6 have the same value, the outputs of the OR gate U5 and the NOR gate U6 are added to the OP amplifier U4. Is input to the inverting terminal of. The non-inverting terminal of the OP amplifier U4 has a voltage corresponding to half of a driving voltage.

This is applied to amplify the output signal of the ASK modulator 20. At this time, the input and output signals of each part are as shown in FIG. Here, (a) is a waveform of the transmission clock signal CLK output from the UART (10) and (b) is a waveform of the transmission data (TxD) output from the UART (10). (c) is the output waveform of the OR gate U5 and (d) is the output waveform of the NOR gate U6. (e) is a waveform output from the OP amplifier U4 and corresponds to the sum of the output of the OR gate U5 and the output of the NOR gate U6. The waveform is ASK-modulated and there is always no DC component. Can be sent far away. The modulated signal output from the ASK modulator 20 carries a carrier frequency of one cycle on data of one bit "0", so that the bandwidth of this carrier is equal to the bandwidth of the data to be transmitted.

이 인가된 OP앰프(U3)의 비반전단자와 접속되어 있다. 여기서 변압기(T)는 선로특성 임피던스가 600Ω)이고, 1 : 1 음성대역용 변압기를 사용하여 본체에서 가입자전용 키폰전화기에 음성채널용 변압기와 함께 두 변압기의 중간탭(TAP)을 이용하여 전력을 공급한다.On the other hand, the inverting terminal of the resistor R5, the feedback resistor R4, and the OP amplifier U3, whose primary side is connected to the data line and one end of the secondary side is connected to the output terminal of the OP amplifier U4. Is connected to the other end, the voltage corresponding to half of the driving voltage

It is connected to the non-inverting terminal of the applied OP amplifier U3. Here, the transformer (T) has a line characteristic impedance of 600 Ω), and the power is supplied from the main body to the subscriber-only key phone by using the transformer for the voice channel and the middle tap (TAP) of the two transformers. Supply.

In the OP amplifier U3 having the feedback resistor R4, the received carrier signal amplified through the hybrid circuit 30 is amplified, and the signal input to the inverting terminal of the OP amplifier U3 is shown in FIG. Has the same waveform as At this time, the hybrid circuit 30 and the OP amplifier U3 separate the transmission signal and the reception signal. However, since the transmission and reception signals cannot be completely separated due to the characteristics of the transmission line and the hybrid circuit 30, the output signal and the reference voltage of the OP amplifier U3 are inputted to the comparator U2 to form a waveform as shown in FIG. The monostable multivibrator U1 is driven as an output signal having a voltage of 1 bit.

The output of the comparator U2 is provided to the inverting input terminal 13 of the OR gate inside the monostable multivibrator U1, and the driving voltage V _α is supplied to the OR gate through the resistors R2 and R3. It is applied to the input terminals A and B, respectively. The output according to the logic value of the OR gate is input to the trigger terminal (not shown in the figure) of the monostable multivibrator U1. The pulse width of the output signal of the monostable multivibrator U1 is determined by the values of the resistors R1 and condenser C1 connected to the T1 and T2 terminals. Adjust

(ready to send) 신호 단안정 멀바이브레이터(U1)의 C단자에 입력하여 단안정 멀티바이브레이터(U1)의 동작을 멈추도록 한다. 이때 하이브리드회로(20)에서 수신테이타와 함께 전송되는 송신데이타의 파형은 제5도의 (a)와 같은 파형을 지니며 (b)는 UART(10)로부터 출력되는

신호의 파형을 나타내고 있으며, (e)는 단안정 멀티바이브레이터(U1)의 출력단자

로부터 직렬송수신부(10)의 수신데이타입력단자(RxD)에 입력되는 상대방으로부터 수신데이타의 파형이다.On the other hand, in order to prevent the transmitted data is received is output from the serial-parallel transmission receiver 10

(ready to send) The signal is input to the C terminal of the monostable multivibrator U1 to stop the operation of the monostable multivibrator U1. In this case, the waveform of the transmission data transmitted together with the reception data in the hybrid circuit 20 has a waveform as shown in (a) of FIG. 5, and (b) is output from the UART 10.

(E) shows the output terminal of the monostable multivibrator (U1).

Is the waveform of the reception data from the other party inputted to the reception data input terminal RxD of the serial transmission / reception unit 10.

In this case, a high accuracy monocular multivibrator should be used for accurate data reception. If the 74HC 4538 of NS (National Semiconductor) is used, the pulse width PW of the monostable multivibrator U1 of the circuit having a transmission / reception rate of 9600 BPS is connected to the T1 and T2 terminals of the monostable multivibrator U1. It is determined by the values of the resistor R1 and the capacitor C1 and the relation is as follows.

PW = 0.7 × R ₁ × C ₁

Here, the unit of PW is seconds, the unit of R ₁ is ohm, and the unit of C ₁ is farad.

이다. C₁으로 0.01μF를 사용한다면 R₁은 14.88KΩ이 나온다. 따라서 R₁을 15Kohm을 사용하고 C₁은 0.01μF를 사용하면 Pw = 105μSec이며, 이는 본래의

초의 0.8%의 오차가 있으므로 간단히 사용할 수 있다.Since the data transfer rate in the present invention should be equal to the pulse width (PW) of the monostable multivibrator

to be. Using 0.01 μF for C ₁ , R ₁ yields 14.88 KΩ. Therefore, using R ₁ with 15 Kohm and C ₁ with 0.01 μF, Pw = 105 μSec, which is the original

There is an error of 0.8% of the second, so it is easy to use.

However, the rate of change of temperature of C ₁ and R ₁ should be small and parts with less than 1% error should be used if possible.

As described above, the data transmitting / receiving apparatus of the key phone system according to the present invention can configure the data communication between the main body and the subscriber-only telephone by using a logic element and an analog element in a very simple manner. It is very economical because the area of components can be minimized.

In addition, the data transmission and reception apparatus of the key phone system according to the present invention is asynchronous half-duplex (ping-pong) method that can exchange the transmission and reception data with a certain period (Ha

lf-Duplex) and can be used as a modem with a transmission distance of about 500 meters.

Claims (4)

A serial-parallel transmission / reception unit 10 for serially transmitting data transmitted in parallel from the microprocessor and interfacing the data received in series from the reception unit to the microprocessor in parallel; An ASK modulator 20 for inputting binary data from the serial-parallel transmitter / receiver 10 to carry a carrier frequency of one cycle in one-bit " 0 "data; A hybrid circuit 30 which transmits a transmission signal from the ASK modulator 20 to a receiver and transmits a signal received from the receiver; And a receiving unit 40 for separating the transmission data contained in the data received from the hybrid circuit 30 according to the RTS signal from the serial and parallel transmission and reception unit 10 and outputting only the reception data. Data transceiver. The OR gate U5 of claim 1, wherein the ASK modulator 20 inputs the transmission data TxD and the transmission clock signal CLK outputted from the serial-parallel reception unit 10 and outputs them according to a logical combination value. )Wow ; An inverter U7 for inverting and outputting the transmission clock signal CLK; And a NOR gate (U6) for inputting the outputs of the transmission data (TxD) and the inverter (U7) and outputting them according to a logical combination value. 2. The hybrid circuit of claim 1, wherein the hybrid circuit 30 is connected to the inverting terminal in parallel with two predetermined resistors R7 and R8, and a voltage corresponding to half of the driving voltage is applied to the non-inverting terminal. An OP amplifier U4 which adds and amplifies the output of the modulator 20; The primary side is connected to the data line, the secondary side is connected to a predetermined resistor (R5) and the receiving unit 40, the main body of the key phone system comprising a transformer (T) for coupling to the subscriber-only telephone Data transmission and reception device. The receiver of claim 1, further comprising: an amplifier (41) for amplifying a signal output from the hybrid circuit (30); A comparator 42 for comparing and outputting a signal output from the amplifier 41 and a reference voltage; The output signal of the comparator 42 is supplied to an inverting input terminal B of an OR gate to which a predetermined driving voltage is applied and a predetermined resistance R3 is connected, and the predetermined driving voltage supplies a predetermined resistance R2. The OR signal is input to the input terminal A of the OR gate, the output signal of the OR gate is input to the trigger terminal, the driving voltage is connected to the T2 terminal through the resistor R1, and one end of the capacitor is grounded. And a monostable multivibrator circuit (43) connected to the data transmission and reception device for a key phone system.

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