KR970002947B1 - Driving apparatus for transmitting signal - Google Patents

Abstract

The present invention is to provide an apparatus for transmitting signal. The apparatus for transmitting signal according to the present invention comprises: a first AND logical gate(A1) receiving transmission enable signal(TXE) and transmission data signal(TXD); D flipflop(DF1) of which input is output signal of said AND logical gate(A1) and synchronizing signal is a transmission clock signal; XOR logical gate of which inputs are output signal(Q,D) flipflop(DF1) and the transmission clock signal; an inverting means(11) for inverting a receipt recognition signal(CRS) which determines whether there is a signal of media; NAND logical gate(N1) of which inputs are receipt recognition signal(CRS) and the transmission enable signal(TXE), for generating a control signal(STX) controlling the receipt recognition signal(CRS) if the receipt recognition signal(CRS) is received during preparation of transmission; a second AND logical gate of which inputs are transmissin enable signal(TXE) and transmission clock signal(TXC) and inverted receipt recognition signal(CRS); and a transmission driving means(TX Drv) for receiving a signal from said second AND logical gate and transmitting automatic outputs to the media. Thereby, the present invention can prevent collision when transmitting signals.

Description

Signal transmission drive device and control method

1 is a circuit diagram of a signal transmission driving apparatus according to the prior art.

2 is a transmission control flowchart of the signal transmission driving device of FIG.

3 is a signal waveform diagram of FIG.

4 is a circuit diagram of a signal transmission driving apparatus according to the present invention.

5 is a transmission control flowchart of the signal transmission driving device of FIG.

6 is a signal waveform diagram of FIG.

* Explanation of symbols for main parts of the drawings

A1, A2, A3: logical AND circuit N1: negative AND circuit

I1: Inverter XOX: Exclusive logic circuit

DF1: Deflip Flop

The present invention relates to a signal transmission driving device and a control method thereof, and more particularly, to a signal transmission driving device and a control method for preventing a collision that may occur in the medium when the signal received from the terminal to start transmission is detected.

The conventional signal transmission driving apparatus uses the transmit enable signal TXE, the transmit data signal TXD, and the transmit clock signal TXC as inputs, and transmit drive output signals TX + and TX. -), And as shown in FIG. 1, the logical AND circuit A1 receiving the transmission enable signal TXE and the TX data signal TXD and the logical AND circuit A1 A deflip-flop DF1 for adjusting an output Q in synchronization with the transmission clock signal TXC, an output Q of the deflip-flop DF1, and the transmission clock signal TXC. ) Exclusive logic circuit (XOR) as the input, the logical AND circuit (A2) for inputting the output signal of the transmit enable signal (TXE) and exclusive logic circuit (XOR), and the logical AND circuit (A2) It consists of a transmission drive stage (TX Drv) which takes in the output of the input.

The transmission drive stage TX Drv is a driving stage for differentially outputting a transmission signal and transmits differential outputs TX + and TX- to a medium for transmission. The transmission control procedure is shown in FIG. When the frame is ready for transmission, it checks whether the standard interval between frames has passed and whether there is a signal on the medium. If the standard interval has not passed and no signal is detected on the medium, the transmission starts. If this does not occur, the transmission ends.

When the collision occurs, as shown in FIG. 3, the reception detection signal CRS, which detects the presence of the signal of the medium, is low when there is no signal in the medium as shown in (A). At T7 in the beginning (C), the reception detection signal CRS goes high, which is caused by the presence of a signal in the medium.

On the other hand, if a collision occurs, it generates a jam signal indicating a collision and sends it to another terminal, and calculates the number of collisions in itself and abandons transmission when more than 16 times, calculates a delay time when less than 16 times, and waits for the delay time. In order to attempt retransmission, the inter-frame reference interval and the presence of the medium signal are returned to the inspection process.

This transmission process receives the transmission data signal TXD, the transmission enable signal TXE, and the transmission clock signal TXC of FIG. 1 when the transmission is started, and when the transmission enable signal TXE is enabled. The transmission data signal TXD is input to the data of the flip-flop DF1 and is synchronized with the transmission clock signal TXC so that the transmission data signal TXD is an output terminal Q of the deflip-flop DF1. This output is exclusively summed with the transmission clock signal TXC in the exclusive OR circuit XOR to synchronize the transmission data signal TXD which is Non Return to Zero (NRZ) data with the transmission clock signal TXC. The transmit enable signal TXE becomes high by generating Manchester data that changes from a high level to a low level and becomes low at a center of one data section. The man in the interval The input to the transmission driver stage the emitter of data (TX Drv) is accomplished by passing the medium through a differential output.

That is, according to the conventional signal transmission apparatus and the transmission method, a collision occurs on the medium side when a reception signal from the medium is detected during the period in which the transmission enable signal is enabled after the transmission preparation time after detecting the presence of the medium signal. Therefore, in a collision state, transmission must be delayed or abandon transmission, and an error occurs in data of a reception frame, thereby preventing the use of received data.

Accordingly, an object of the present invention is to provide a signal transmission driving apparatus capable of solving the above problems to prevent a collision during signal transmission.

Another object of the present invention is to provide a control method of a signal transmission driving apparatus that can efficiently control the signal transmission driving apparatus.

A signal transmission driving apparatus of the present invention for achieving the above object includes an AND circuit A1 which receives a transmit enable signal TXE and a TX data signal TXD, and an output of the AND circuit A1. Exclusively using the flip-flop DF1 which takes a signal as an input and makes the said transmission clock signal TXC a synchronous signal, the output Q of the said flip-flop DF1, and the transmission clock signal TXC as an input. A logic sum circuit (XOR), an inverter (I1) for inverting the reception detection signal (CRS) for detecting the presence or absence of a signal of a medium, and the reception detection signal (CRS) and the transmit enable signal (TXE) as inputs A logic multiplication circuit A3 which receives a negative logic circuit N1, the transmission enable signal TXE, the transmission clock signal TXC, and the reception detection signal CRS inverted through the inverter I1. ) And a transmission drive for transmitting differential outputs TX + and TX- to the medium with the output of the AND circuit A3 as an input. Characterized in that configured including (TX Drv).

The control method of the signal transmission driving apparatus of the present invention for achieving the above another object is to prepare a frame to check the inter-frame reference interval and the presence of the signal of the medium, and the reference frame between the frame does not pass the received signal from the medium If is not detected, it comprises the steps of preparing for transmission, re-checking whether there is a received signal from the medium after the transmission ready time, and if there is no received signal from the medium is characterized in that it comprises a process for transmitting.

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

As shown in FIG. 4, the signal transmission driving apparatus of the present invention includes a logical AND circuit A1 for inputting a transmit enable signal TXE and a TX data signal TXD, and the logical AND circuit A1. The output signal of the input is a flip-flop (DF1) for adjusting the output (Q1) in synchronization with the transmission clock signal (TXC), the output (Q) and the transmission clock signal of the flip-flop (DF1) An exclusive logic circuit XOR having TXC as an input, an inverter I1 for inverting a reception detection signal CRS for detecting the presence or absence of a signal of a medium, the reception detection signal CRS, and a transmission enable signal A negative logic circuit N1 for outputting a control signal STX for controlling when a reception detection signal CRS is generated at a transmission preparation time by inputting the TXE as an input, and the transmission enable signal TXE and a transmission Logic circuit for inputting the clock signal TXC and the reception detection signal CRS inverted through the inverter I1. And a transmission drive stage TX Drv for inputting the output of the AND circuit A3, and having no signal received from the medium with the reception detection signal CRS low. If (TXE) is high, transmission is performed by connecting the differential outputs TX + and TX- to the medium from the transmission drive stage TX Drv.

On the other hand, if there is a signal received from the medium in which the reception detection signal CRS is in a high state, the transmission signal is not input to the transmission driver.

In the control method of the signal transmission driving apparatus, as shown in FIG. 5, when a frame to be transmitted is prepared, the reference interval between frames and the presence or absence of a signal of the medium are examined, and the reference interval has not passed and the signal of the medium is not detected. If the receiving detection signal (CRS) of Fig. A is low, it is ready to transmit. After the preparation time, as shown in Fig. 2B, the receiving detection signal (CRS) is again checked to see if there is a receiving signal from the medium. If there is no received signal, transmission is performed. That is, if the reception detection signal CRS is detected high between the transmission preparation time, the signal is returned to the transmission standby state and ready for retransmission after the reception frame is completed.

After the transmission, it checks whether there is a collision during transmission until the transmission is completed. If the collision does not occur, the transmission is terminated. If the collision occurs, the jam signal indicating the collision is generated in the same manner as before, and is transmitted to other terminals. In order to calculate the number of collisions, it will give up the transmission if it is more than 16 times, and if it is less than 16 times, calculate the delay time, wait for the delay time, and then return to the inspection process the inter-frame reference interval and the presence of the medium signal to try retransmission. .

As described above, according to the present invention, there is an effect that the signal transmission time can be shortened and the transmission efficiency can be improved by eliminating the signal collision that may occur in the medium to eliminate the transmission delay and the abandonment caused by the collision.

Claims (2)

A logical multiplication circuit A1 for inputting the transmit enable signal TXE and a transmission data signal TXD, and an output signal of the logical multiplication circuit A1 are input, and the transmission clock signal TXC is a synchronization signal. A reception signal for detecting the presence or absence of a signal of a medium; and a double logic flop circuit DF1, an exclusion logic circuit XOR for inputting the output Q of the deflipflop DF1 and the transmission clock signal TXC. A negative logic circuit N1 which outputs a control signal STX for controlling the reception detection signal CRS when the detection detection signal CRS and the transmission enable signal TXE are input, and the reception detection signal CRS is generated during a transmission preparation time; An AND circuit A3 for inputting the TX enable signal TXE, the TX clock signal TXC, and the reception detection signal CRS inverted through the inverter I1, and the AND circuit A3. Including a transmission drive stage (TX Drv) for transmitting differential outputs (TX +, TX-) to the medium with the output of Signal transmission drive, characterized in that. Preparing a frame and checking whether there is a reference interval between frames and whether there is a signal in the medium; if the reference interval between frames has not passed and a received signal from the medium is not detected, preparing for transmission; And re-inspecting whether there is a received signal, and transmitting if there is no received signal from the medium.