JPH0824271B2 - Transmitter - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a transmitter connected to a data transmission bus for transmitting data, and particularly to a transformer isolated transceiver having improved characteristics when data is not transmitted.

(Prior Art) When data transmission is performed using a cable, an electric signal that does not include a DC component such as a frequency shift keying (FSK) signal may be used.

FIG. 4 is a configuration circuit diagram of a conventional transformer isolation transceiver used for transmitting an FSK signal. In the figure, TX
ON is an on / off control signal, TXD is a transmission logic signal, RXD is a reception logic signal, and L ₁ and L ₂ are cable signals flowing in the cable. 1 is a line driver controlled by the TXON signal,
A constant current signal is complementarily output from two output terminals according to the binary value of the TXD signal. That is, for one output terminal, the constant current signal is turned on and off according to the TXD signal.
Reference numeral 2 is a receiving unit that converts a signal input via a cable into an RXD signal, and includes a comparator. Reference numeral 3 is a transformer that insulates the cable from the line driving unit 1 and the receiving unit 2, and 4 is a DC power source that supplies a midpoint voltage to the transformer 3, and considers the output voltage of the line driving unit 1 and the input voltage of the receiving unit 2. Determined.

The operation of the device thus configured is as follows.
When transmitting, the line driver 1 is turned on by the TXON signal, and a signal corresponding to the TXD signal is transmitted to the cable,
Generate signals L ₁ and L ₂ . When receiving, the line driving unit 1 is turned off by the TXON signal, and the signals L ₁ and L ₂ are received from the cable via the receiving unit 2 and converted into the RXD signal and sent.

The bus used in this transmitter is a (direct) parallel connection type or a tree type bus using an impedance matching tap.

(Problems to be Solved by the Invention) However, when the two output terminals of the line driving unit 1 are turned off by the TXON signal, a high impedance property in which the load effect seen from the cable side can be ignored cannot be obtained. As a result, there was a problem that the number of transceivers connected to the bus was limited. For example, an open collector
If a driver IC with a transistor (specifically, model name MC10192 manufactured by Motorola Co., Ltd.) is used, the transistor off characteristics during transmission off are insufficient, and ideally a leakage current of 0 mA is desirable, but in reality A leakage current of about 2mA flows through this. For this reason, a leakage current flows even though the line driving unit 1 is off, so that the impedance does not become high when viewed from the cable side.

The present invention solves such a problem, and an object of the present invention is to realize a transmitter having a sufficiently high impedance when transmission is off such as reception.

(Means for Solving Problems) According to the present invention which achieves such an object, a line driver (1) which complementarily outputs a constant current signal from two output terminals according to a transmission logic signal (TXD) is provided. , In the transmitting state, turn on the line driving unit, and in the non-transmitting state, control signal (TXON) to turn off the line driving unit, and connect the two output terminals of the line driving unit to the primary winding. , A transformer (3) for outputting the binary signal (L ₁ , L ₂ ) appearing in the secondary winding to the cable, and a DC power supply (4) for supplying the midpoint voltage (E ₂ ) to the primary winding of the transformer The transmitting device having the following is configured as follows.

That is, the two output terminals of the line driving section and the two windings respectively connected to the primary winding of the transformer are connected.
A diode (5a, 5b), two bleeder resistors (63a, 63b) connected in series that connect between the two output terminals of the line driver, and a reverse bias voltage (E ₁ ) A switch means (6) inserted in a line supplied to a common connection point of the bleeder resistance, the switch means being turned on to supply a reverse bias voltage to the diode when the control signal is off, When the signal is on, the switch means is turned off to release the reverse bias voltage supplied to the diode.

(Operation) In the transmission state, since the control signal is turned on, a complementary constant current signal corresponding to the communication logic signal is output from the two output terminals of the line drive section and sent to the primary winding of the transformer.
At this time, since the switch means is off, the reverse bias voltage is not applied to the diode, and the diode does not affect the transmission.

In the non-transmission state, the control signal is turned off, so that the line driver is turned off, but a leakage current flows. At this time, since the switch means is turned on, a reverse bias voltage is applied to the diode via the bleeder resistance. Then, the diode is in a high impedance state, the leakage current of the line driving unit is cut off from the primary winding of the transformer, and the high impedance state is secured when viewed from the cable side.

The present invention will be described below with reference to the drawings.

FIG. 1 is a configuration circuit diagram showing a first embodiment of the present invention. In FIG. 1, the same reference numerals are given to those having the same functions as those in FIG. 4, and the description thereof will be omitted.

In the figure, 5 is a diode inserted in the line connecting the output terminal of the line driving unit 1 and the transformer 3, and is connected so that the case where a current is supplied from the output terminal is in the forward direction. Since the line driving unit 1 switches between the two output terminals and outputs, the corresponding subscripts a and b are added to the diode 5 accordingly.
To distinguish them. The diode 5 is an element that has a sufficiently high impedance with respect to the transformer 3 when a reverse bias voltage is applied, and has a sufficiently small electrostatic capacitance and a high resistance.

6 is a transistor for applying a reverse bias voltage to the diode 5, 61 is a base control unit for turning on / off the transistor 6 according to an on / off control signal, and 62 is a direct current for supplying the reverse bias voltage to the diode 5 via the transistor 6. A power source 63 is a bleeder resistor that determines a predetermined current _ID flowing through the diode 5.

When the TXON signal is on, it is assumed that the output terminal on the diode 5a side is on and the output terminal on the diode 5b side is off by the TXD signal. At this time, the current I _D represented by the following equation flows through the diode 5b on the output terminal side which is turned off.

I _D = (V _T −V _Da −V _Db ) / 2R (1) where V _T is the input voltage of the transformer 3, V _Da is the forward voltage of the diode 5a, and V _Db is the forward voltage of the diode 5b. Voltage and R are values of the bleeder resistors 63a and 63b, and both values are selected to be equal here.

Then, the diode 5b on the output terminal side, which has been turned off by the current _ID , is held in the on state. With this configuration, when the output terminal changes from off to on due to the TXD signal, it is not necessary to turn on the diode 5b, and a good transmission waveform with no response delay can be obtained. Incidentally, TX
When the ON signal is on, the transistor 6 is off, and the reverse bias voltage is not applied to the diodes 5a and 5b.

Next, the resistance value R of the bleeder resistance 63 is determined as follows. It is desirable that the resistance value R is larger because the power loss is smaller, but
On the other hand, when the output terminal is off, the diode 5 needs to have a value capable of supplying a sufficient reverse bias voltage. Therefore, the resistance value R is determined by the following equation.

R <(E ₁ −E ₂ −V _RECMAX −V _CE ) / I _OFFMAX (2) The operation of the apparatus thus configured will be described below. FIG. 2 is a waveform diagram for explaining the operation of the apparatus shown in FIG.
Is a control signal TXON, (B) is a transmission logic signal TXD, (C) is a positive drive terminal current of the line driver 1, and (D) is a line driver 1.
(E) is the line voltage of the cable.

When the control signal TXON is on, the line driver 1 is in the transmitting state. Depending on the ON / OFF (H, L) of the transmission logic signal TXD,
A current Isink complementarily flows at the positive drive terminal and the negative drive terminal of the line drive unit 1. Here, the positive drive terminal is the output terminal on the side marked ON in FIG. 1, and the negative drive terminal is the output terminal on the side marked OFF in FIG. The current Isink is a constant current drive value that flows from the output terminal that is turned on, and is set to, for example, 16 mA. The ratio between the number of turns N ₁₁ and N ₁₂ between both sides of the primary winding and the center tap of the transformer 3 and the number of turns N ₂₂ of the secondary winding are equal (N ₁₁ : N ₁₂ : N ₂₂ = 1: 1: 1). Then, + Eout and −Eout appear alternately in the line voltage of the cable.

Further, since the base control unit 61 is turned off by the control signal TXON, the reverse bias voltage is not supplied to the diodes 5a and 5b, and the signal ± Eout is supplied to the cable via the transformer 3.
Appears. Here, one of the positive drive terminal and the negative drive terminal of the line drive unit 1 is turned off by turning on and off the transmission logic signal TXD. However, the diodes 5a and 5b connected to the off terminal side have bleeder resistance. It is turned on by 63a and 63b. In FIGS. 2C and 2D, the current at the OFF terminal is zero, but strictly speaking, the leakage current Ioff is about 2 mA.

When the control signal TXON is off, the line driver 1 is in the non-transmission state, and in the case of FIG. 1, it shifts to the reception state. Since the base control unit 61 is turned on by the control signal TXON, the reverse bias voltage is supplied to the diodes 5a and 5b by the DC voltage E ₂ via the transistor 6. Then diode 5
The a and 5b are completely turned off, and even if the leakage current Ioff flows through the positive drive terminal and the negative drive terminal when the line drive unit 1 is in the off state, it is in a high impedance state when viewed from the cable side.

FIG. 3 is a constitutional circuit diagram showing a second embodiment of the present invention. The diode 7 is inserted with the polarity reversed from that of the diode 5 of the first embodiment. Reference numeral 8 is a transistor for applying a reverse bias voltage to the diode 7, 81 is a base control unit for controlling the transistor 8 according to the TXON signal, and 82 is a DC power supply for supplying the reverse bias voltage to the diode 7, which is the reverse of the first embodiment. It is polar. 83 is a bleeder resistance.

The circuit having this configuration operates according to the first embodiment.

In the above embodiment, the DC power supply 4 that generates the DC voltage E ₂
, And a DC power source 62 (or 82) for generating a DC voltage E ₁ is provided, but these DC voltages E ₂ and E ₁ may be zero volts in relation to the potential of the line driver 1.

(Effects of the Invention) As described above, according to the present invention, even if the diodes 5a and 5b are inserted between the line driving unit 1 and the transformer 3 and the line driving unit 1 is turned off during non-transmission, the impedance is sufficiently high. Even if the state is not obtained, since a reverse bias voltage is applied to this diode, there is an effect that a sufficiently high impedance state can be obtained as seen from the cable side during non-transmission.

[Brief description of drawings]

FIG. 1 is a structural circuit diagram of the first embodiment of the present invention, FIG. 2 is a waveform diagram for explaining the operation of the apparatus of FIG. 1, FIG. 3 is a structural circuit diagram of the second embodiment, and FIG. The figure is a connection diagram of a conventional device. 1 ... Line drive part, 3 ... Transformer, 5 ... Diode, 6 ... Transistor (switch means), TXD ... Control signal.

Claims (1)

[Claims] 1. A line driving unit (1) which complementarily outputs a constant current signal from two output terminals according to a transmission logic signal (TXD), and in the transmitting state, this line driving unit is turned on and non-transmission is performed. In this state, the control signal (TXON) that controls this line driver to turn off.
And a transformer (3) for connecting the two output terminals of the line drive section to the primary winding and outputting the binary signals (L ₁ , L ₂ ) appearing in the secondary winding to the cable, In a transmitter equipped with a DC power supply (4) for supplying a midpoint voltage (E ₂ ) to a primary winding of the transformer, a line connecting two output terminals of the line driver and the primary winding of the transformer. Two diodes (5a, 5b) respectively inserted in the two, two bleeder resistors (63a, 63b) connected in series for connecting between the two output terminals of the line driver, and a reverse bias Switch means (6) inserted in a line for supplying a voltage (E ₁ ) to the common connection point of the bleeder resistance, and the switch means is turned on when the control signal is off to reverse-bias the diode. Voltage is supplied, and the switch is turned on when the control signal is on. Chi means transmitting apparatus characterized by releasing the reverse bias voltage supplied to the diode off.