JPS6258750A - Data interface circuit - Google Patents

Abstract

PURPOSE:To reduce power consumption by making larger the output impedance of a driver in an idle time. CONSTITUTION:Since, in a data transmission time, a control signal representing that a data is in transmission is added on a control circuit 13 from a data transmission control circuit 17, the control circuit 13 controls a switch circuit 12 so as to be made on. Thereby, a resistor R3 is short-circuited and an impedance becomes a prescribed one by a resistor R0. Also, in the idle time, the control circuit 13 controls the switch circuit 12 so as to be made OFF. Thereby, the resistor R3 is connected to the resistor R0 in series, making larger the output impedance. Therefore, so that the output impedance becomes large even when the output voltage of a driver 11 is between +5V-+15V of high level or between -5V--15V of low level, an output current is reduced.

Description

[Detailed Description of the Invention] [Summary] In a data interface circuit having a predetermined output impedance, the output impedance is increased during idle to reduce the output current of the driver, thereby reducing power consumption during idle. It is.

[Industrial application field]

The present invention relates to a data interface circuit for connecting various devices.

The data interface circuit has a standardized connection configuration, for example, the Electronic Industries Association (EI)
A; Electronic Industry
s As5o-cation) Standard R3-232C
Configurations based on this are widely adopted. This R3-23
2C applies to both asynchronous and synchronous serial binary data transmission in full-duplex and half-duplex communication systems with transmission speeds up to 20 K b/s. Data terminal equipment (DTE) to which this standard applies include teleprinters, CRT display devices, front-end boats,
There are devices such as processors, and data line termination equipment (D
CE) includes modems and home line termination equipment (DS).
U) etc.

Also, as for the electrical characteristics of this R3-232C, the input impedance is 3 to 7Ω, and the output impedance is 300Ω.
Ω or more, when the output voltage Vout is 3 to 7 Ω, +
5V<Vout <+l 5V, -5V>Vout
> -15V. The pin arrangement of the connector is also specified, and a 25-pin connector with 13 pins in the upper row and 12 pins in the lower row is used.The male connector is for the data terminal equipment (DTE) side, and the female connector is for the data line termination equipment (DTE) side.
CE) side.

[Conventional technology]

In conventional data interface circuits, the driver and the receiver of other devices are connected by cables, and the receiver and the driver of other devices are connected by cables, respectively, and the input impedance and output impedance are selected according to standard methods such as R3-232C. has been done.

For example, as shown in FIG. 3, a resistor R is connected to the output terminal of the driver 31 as an output impedance.

A cable 32 is connected through the cable 32, and a receiver 33 of a partner device is connected to this cable 32. In this counterpart device, resistors R1 and R2 are connected to the input terminal of the receiver 33 so as to provide a predetermined input impedance.

The output voltage of the driver 31 is, in the case of R3-232C,
As mentioned above, the high level is +5V to +15V, and the low level is -5V to -15V. It will be received at

[Problem that the invention seeks to solve]

The driver 31 has an output level of either a high level or a low level in an idle state where data is not being transmitted. Therefore, even in an idle state, the output level is output through the resistors R1 and R2 of the other device. Therefore, the current from the driver 31 flows. In other words, current flows through the driver 31 from the moment the partner device is connected, consuming power.

The present invention aims to reduce power consumption during idle time.

[Means for solving problems]

The data interface circuit of the present invention switches output impedance to reduce power consumption.
To explain with reference to the figure, it is equipped with a switch circuit 2 that switches the output impedance (Ro, R3) of the driver 1, and a control circuit 3 that controls the switch circuit 2. The receiver 5 of the other device is connected to resistors R, , R2 so as to have a predetermined input impedance.

During data transmission, the output impedance is switched to a predetermined value by the switch circuit 2, and when idle,
The switch circuit 2 switches the output impedance to a larger value.

[Effect]

During data transmission, the output impedance is a predetermined value, so an output current corresponding to the transmitted data flows from the driver 1, and when idling, the output impedance becomes thick (so
The output current from driver 1 becomes smaller. Therefore, power consumption during idle time can be reduced.

〔Example〕

Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 2 is a block diagram of an embodiment of the present invention, in which 11 is a driver, 12 is a switch circuit consisting of transistors, etc.
13 is a control circuit that controls the switch circuit 12; 14.2
1 is the cable, 15 is the receiver of the other device, 16.19
17 is a protection circuit, 17 is a data transmission control circuit, 18 is a receiver, 22 is a driver of a partner device, +V and -V are power supply voltages, and R6-R5 are resistors.

The output impedance of the driver 11 is a resistor R.

, R3, and the input impedance of the other device is determined by the resistors R, , R2. Furthermore, the input impedance of the receiver 18 that receives data from the other device is determined by resistors R4 and R5.

The aforementioned input impedance is selected to be between 3 and 7 ohms for R3-232G. Further, the switch circuit 12 short-circuits the resistor R3 to reduce the output impedance when in the on state, and connects the resistor R3 in series to the resistor R8 to increase the output impedance when in the off state.

During data transmission, a control signal indicating that data transmission is in progress is applied from the data transmission control circuit 17 to the control circuit 13.
The control circuit 13 controls the switch circuit 12 to be in the on state. As a result, the resistor R3 is short-circuited, resulting in a predetermined output impedance due to the resistor R. Therefore,
When transmission data is added from the data transmission control circuit 17 to the driver 11, +5V to +15V is applied corresponding to the data.
(2) A high level output signal or a low level output signal of -5V to -15V, and the output signal is a resistor R.

The signal is sent to the cable 14 via the device, and in the other device, the voltage is divided by resistors R, , Rz and applied to the input terminal of the receiver 15.

Further, during idle time, a control signal is applied from the data transmission control circuit 17 to the control circuit 13 indicating that the data transmission is not in progress but in an idle state, so the control circuit 13 controls the switch circuit 12 to be in the OFF state. As a result, the resistor R3 is connected in series with the resistor R8, increasing the output impedance. Therefore, even if the output voltage of the driver 11 is at a high level of +5V to +15V or a low level of -15V to -15V, the output impedance becomes large and the output current becomes small.

The output voltage sent from the driver 11 to the cable 14 is
Since the smaller the output impedance is, the larger the output impedance can be, it is desirable that the output impedance be as small as possible. However, as mentioned above, R3-2
According to the 32C standard, the resistance is 300Ω or more, so it cannot be made smaller than this. Therefore, the output impedance during data transmission is set to 300Ω, and the switch circuit 1 is set so that the output impedance is several tens of Ω during idle.
2 to switch.

As for data from the other device, an output signal from the driver 22 is transmitted via the cable 21 and received by the receiver 18, and the received signal is applied to the data transmission control circuit F.

In addition, protection circuits 16 and 19 protect the driver 11 and receiver 18 from input voltages or noises exceeding the power supply voltages +V and -V.
Zener diodes are connected in opposite directions to the ground, and diodes are connected in opposite directions between the +V power source and the -V power source. It has the following.

The present invention is applicable not only to data interface circuits of R3-232C (but also to data interface circuits of other interface standards).

[Effects of the Invention] As explained above, the present invention controls the switch circuit 2.12 by the control circuit 3.13 to increase the output impedance of the driver 1.11 during idle, thereby increasing the output impedance of the driver 1.11 during idle. There is an advantage that the output current becomes small at times, and power consumption can be reduced.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram of the principle of the present invention, FIG. 2 is a block diagram of an embodiment of the present invention, and FIG. 3 is an explanatory diagram of a conventional example. 1.11.31 is a driver, 2.12 is a switch circuit,
3 and 13 are control circuits, 4, 14, 21° and 32 are cables, 5, 15, 18 and 33 are receivers, 16 and 19 are protection circuits, 17 is data transmission control circuit, Ro and R3 are resistors as output impedance. , R, , R2, R, , R5 are resistances as input impedances.

Claims (1)

[Claims] A switch circuit (2) that switches the output impedance of a driver (1) connected to a data transmission line, and a control circuit that controls the switch circuit (2) so as to increase the output impedance during idle. (3) A data interface circuit comprising: