JPH0467826B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a data input/output device having an asynchronous interface.

[Conventional technology]

When transmitting and receiving data, various methods are used to determine the timing for transmitting data from a data source to a data receiver.

First, the data source sends data continuously at a predetermined transmission speed after a response procedure to start sending data, and the receiving side unconditionally accepts and processes the data. There is.

In such a system, the receiving side is required to have the ability to immediately process the received data without any delay. If data reception fails during the process, take action by requesting retransmission.

Generally, when the transfer speed of such data is high, printers and the like whose processing speed is extremely slow are provided with a buffer memory for storing a certain amount of received data. The buffer memory temporarily stores received data that cannot be processed immediately to ensure high-speed data transmission.

Therefore, within the capacity of this buffer memory, all data can be received at once and then printed out at an appropriate speed.

However, if data is continuously transferred beyond the capacity of this buffer memory, there is a risk that the data that cannot be stored in this buffer memory will be lost.

Therefore, when this buffer memory becomes full, a procedure is normally performed to temporarily prohibit the data transmission source from transferring any more data.

At this time, the receiving side outputs a busy signal (data reception impossible signal) to the data transmitting source.

The data transmission source stops the data transfer process while this busy signal is being output, and waits for the busy signal to be released.

There is also a well-known system in which a predetermined busy signal is created in accordance with the data processing capacity of various circuits on the receiving side, and is output to the data source at a timely manner, not just the capacity of the buffer memory. .

For example, there is a method in which a data source sends data in units of one word to a receiving side, and the receiving side outputs a busy signal each time it receives this and is ready to accept the next word of data. .

FIG. 3 shows a data transfer process and a timing chart of a busy signal in such a system. For example, this one word worth of data 19 is
Between start bit 1 and stop bit 2,
The configuration is such that 8-bit data 3 is inserted. (Figure a).

When the receiving side receives this stop bit 2,
Busy signal 4 is output from the receiving side (b in the same figure),
When this busy signal is released, the next one word of data is sent from the transmission source again. Such a transmission/reception method is called a step synchronization method, and for this operation, the receiving side is generally provided with an interface that has a function of outputting a busy signal according to the reception capability.

Normally, this busy signal is fixed in advance at a constant period depending on the receiving capability and the characteristics of the data transmission path, and is constantly output from an oscillator or the like.
The data transmission speed determined by this period is called the baud rate, and is selected to be a constant value at the system explanation stage. This baud rate is also well known as an indicator of the data transmission capability of the system.

[Problem that the invention seeks to solve]

However, for example, when a cathode ray tube display is installed on the receiving side and an operator monitors the contents of the received data, when the screen is scrolled, the data transfer speed is too fast and it becomes difficult to read the characters on the screen. It may happen.

If the screen is to be scrolled at a desired speed regardless of the data transfer speed, a large capacity buffer memory will be required, which will increase equipment costs.

Further, setting the data transfer speed to a low speed in advance is not preferable because it reduces efficiency when a large amount of data is to be transferred at high speed.

Although it is not impossible to change the baud rate on a system that is already in operation, it usually requires stopping the system and converting the circuit board or changing the settings for the circuit's operating conditions. , it is impractical to make such changes frequently.

The present invention has been made focusing on the above points,
The object of the present invention is to provide a data input/output device that allows an operator to easily control and change the data transfer rate on the receiving side.

[Means for solving problems]

The data input/output device of the present invention has an asynchronous interface, and this interface includes a data receiving section that receives data, and a data receiving section that performs data transfer processing from a data transmitting source during data receiving work. A busy signal transmitting section is provided that outputs a busy signal for requesting prohibition of. Furthermore, the present invention is characterized in that, apart from this, an operating means is provided for creating a busy signal of arbitrary length and outputting it to the busy signal sending section.

Here, it is preferable that the operating means generates busy signals having two or more types of cycles and selects and outputs one of them.

In addition, the busy signal sending unit calculates the logical sum of a busy signal that is separately created according to the reception capability of the device and a busy signal that is created by the operating means, and sends this to the data sending source. It is a good idea to output it.

[Effect]

In this way, an operating means for creating and outputting a busy signal of an arbitrary period is provided, and the output period of the busy signal is delayed, for example, while the operator is working on receiving data.

This allows the scrolling speed of the cathode ray tube display to be changed to a desired speed. It is also easy to return to the original speed.

Furthermore, if the logical sum of the busy signal corresponding to the reception capability of the device and the busy signal obtained by the operator operating the operating means is output, the normal receiving operation can be resumed immediately after the operation of the operating means is stopped. The state can be restored.

〔Example〕

(Description of Block) FIG. 1 is a block diagram showing an embodiment of the data input/output device of the present invention.

Here, a data transmission source 10 consisting of a host computer, etc., and an input/output device 11 provided at the entrance of a circuit for receiving data are illustrated.

Data received by this input/output device 11 is supplied to various devices (not shown) such as a printer and a video display.

The data transmission source 10 includes a data transmission section 12 that transmits predetermined data, and a busy signal monitoring section 13 that allows or prohibits the data transmission processing operation of the data transmission section 12.

This busy signal monitoring section 13 is connected to the input/output device 11.
This circuit inhibits the data transfer processing operation of the data transmitter 12 when the busy signal 14 is output from the data transmitter 12 . It is assumed that a signal of high level "1" is input here when the busy signal 14 is outputted, and a low level "0" signal is inputted when the busy signal 14 is not outputted.

The input/output device 11 includes an interface 1 consisting of a data receiving section 16 and a busy signal sending section 17.
8, an operating means 24 consisting of a frequency dividing circuit 21, a selector 22, and a selection switch 23.

The data receiving unit 16 is a circuit that receives data 19 from the data transmission source 10 and outputs a busy signal 161 for a certain period of time for processing, for example, each time one word of data is received.

The busy signal sending unit 17 is constituted by an OR circuit, and calculates the logical sum of the busy signal 161 outputted from the data receiving unit 16 and the busy signal 241 outputted from the operating means 24, This is a circuit that outputs to 13.

The frequency dividing circuit 21 of the operating means 24 is a circuit that divides the frequency of a control clock signal 25 supplied from the outside and outputs pulse signals of several frequencies.
The selector 22 is a circuit that selects one of several types of pulse signals output from the frequency dividing circuit 21 in response to a selection signal 231 from the selection switch 23 and outputs it to the busy signal sending section 17.

(Device operation) The above device operates as follows.

First, when normal data transfer processing is being performed, the data receiving unit 16 sends a busy signal 4 (b) every time it receives one word of data 19 (a), as shown in FIG. The operation of outputting for a time t is repeated. This busy signal 4 is the OR gate 1
7 and is output as is to the busy signal monitoring unit 13 of the data transmission source 10.

In this way, data transfer processing is repeatedly performed at a cycle corresponding to the repeat cycle of the busy signal 14.

On the other hand, as shown in FIG.
~213 is output. The first signal 211 (a in the figure) is a signal that is always at a high level "1".
Further, the second signal 212 (b in the same figure) is a signal with a pulse width and pulse interval of t', and the third signal 213 (c in the same figure) is a signal with both a pulse width and a pulse interval of t''. The busy signal 161 outputted from the data receiving section 16 is, for example, a signal whose pulse width and pulse interval are shorter than t' or t''. This is shown in Figure d. If the operator wishes to slow down the scrolling speed of the video display while receiving data, he or she may press the selection switch 23 to send, for example, the third signal 213 to the selector 22.
Suppose that the busy signal is sent to the busy signal sending unit 17 through the bus.
This third signal 213 and the busy signal 161 outputted from the data receiving section 16 are logically summed, and as a result, the busy signal 14 shown in FIG. 3e is outputted from this input/output device 11. become.
This has a pulse width 3t that is three times that of the busy signal 161 output from the data receiving section 16.

This has the same effect as changing the so-called baud rate, for example, making it possible to scroll the screen of a video display at one-third the normal speed.

[Modified example]

The data input/output device of the present invention is not limited to the above embodiments.

For example, the busy signal sending section may include a busy signal oscillator, and the operating means may include only a selection switch to switch the busy signal.

Further, a circuit for freely changing the pulse width of the busy signal using a volume or the like may be provided and this may be used as the operating means.

〔Effect of the invention〕

The data input/output device of the present invention described above can be easily adjusted so that an operator on the data receiving side can receive data at any time and at any data transfer rate. Moreover, when data is to be displayed on a display screen, the screen scrolling speed can be set to a desired value.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing an embodiment of the data input/output device of the present invention, Fig. 2 is a signal waveform diagram of each part showing its circuit operation, and Fig. 3 is a timing chart showing the relationship between data transfer processing and a busy signal. It's a chat. 10... Data transmission source, 16... Data receiving section, 17... Busy signal sending section, 18... Interface, 24... Operation means.

Claims (1)

[Claims] 1. An asynchronous interface, which includes a data receiving unit that receives data, and a device that prohibits data transfer from a data source during data reception. and a busy signal transmitting section that outputs a busy signal to request a busy signal, and further comprising an operating means for creating a busy signal of an arbitrary length and supplying it to the busy signal transmitting section. Characteristic data input/output device. 2. Claim 1, wherein the operating means creates two or more kinds of busy signals with predetermined cycles, selects one of these, and supplies the selected one to the busy signal sending section. Data input/output device as described. 3. The busy signal sending section logically ORs a busy signal separately created according to the reception capability of the device and the busy signal supplied from the operating means, and outputs this to the data sending source. Claim 1 or 2 is characterized in that:
Data input/output device as described in section.