KR19980012611U - Initial delay circuit of auto repeat key - Google Patents

Abstract

The present invention relates to an initial delay circuit of an automatic repeat key, and if the input terminal of the keyboard is kept on, the function corresponding to the input terminal of the keyboard is automatically performed after a predetermined time delay.

In order to realize the initial delay of the automatic repeat key, the present invention includes a microcomputer that recognizes a pulse signal output from a keyboard and processes it according to a program stored in an internal memory device. Thus, there is no need for a counter to count pulse signals for initial delay.

Description

Initial delay circuit of auto repeat key

The present invention relates to an initial delay circuit of an automatic repeat key in which the automatic repeat function operates after a predetermined delay time.

An input device is provided externally so that internal variables required to set operating conditions of industrial devices are adjusted according to a user's purpose.

The keyboard is representative of such input devices, and the operation of industrial equipment is controlled by adjusting internal variables of the device by signals input through the keyboard.

At this time, when the user manipulates the input key to adjust the internal variables to a desired setting value, the function of the input key may be implemented to be automatically repeated for continuous key-on. For example, it can be implemented to automatically perform a desired function repeatedly when the input key is kept on (i.e., held down).

Since the automatic repeating function is not constant for each user to operate the input key on state, the automatic repeating function is provided with an initial delay circuit to be performed after the key-on state lasts for a predetermined time or more.

As an example, the set temperature of the thermostat for keeping the set temperature constant is adjusted through an external keyboard.

At this time, if you want to change the set temperature from 20 degrees to 100 degrees, if you keep the temperature change input terminal of the keyboard on, the set temperature value will be automatically increased by the input signal for the duration. This ascending speed is much faster than the visual judgment speed makes it difficult for the user to turn off the input stage of the keyboard when it is exactly 100 degrees. Therefore, when the user reaches a predetermined temperature (eg, 97 degrees), the user turns off the input terminal of the keyboard (ie, releases the key being pressed), and thereafter performs the operation of repeatedly turning on / off the input terminal of the keyboard. If the auto-repeat function is operated after a certain delay time so that the auto-repeat function does not work even if the on-off time is kept for a certain period of time during the on / off repetitive work, the user's operation keys can be easily set to accurately set the desired value. Can be. The initial delay circuit of the auto repeat key is for this function.

1 is a block diagram of an initial delay circuit of a conventional automatic repeat key.

Referring to this, when the input terminal of the keyboard 1 is turned on, a pulse of a predetermined period is output from a built-in pulse generator (not shown). The output signal is input to the UP terminal of the first counter 2, the CLEAR terminal of the second counter 3, and the AND gate 5, respectively. The output terminal of the second counter 2 is connected to the clear terminal of the first counter 2, and the output of the first counter 2 is input to the AND gate 5. According to the signal input from the AND gate 5, the microcomputer 6 performs a function corresponding to the input signal.

At this time, the UP terminal of the second counter 3 is connected to the output terminal of the pulse generator 4 to count the number of input pulses.

The first counter 2 keeps 8 after counting to 8, and outputs the output (high level) at that time, and the second counter 3 keeps 20 after counting to 20, and then outputs (high level) ). Therefore, when the input terminal of the keyboard 1 is turned on, the first counter 2 counts up to eight, and when it is in the eighth state, it outputs a high level output signal. When the output level of the first counter 2 becomes high, the output signal of the AND gate 5 input to the microcomputer 6 becomes a pulse signal of the keyboard as a result. Therefore, the automatic repeat function (the pulse signal which is continuous according to the maintenance of the on state of the keyboard) is delayed for a period during which the first counter 2 counts up to eight. During this initial delay period, the second counter 3 does not contribute to the initial delay by continually resetting the clear terminal according to the pulse signal from the keyboard 1. When the user recognizes the change value displayed by the auto repeat function and switches the keyboard from the on state to the off state, the second counter 3 counts the pulse input from the pulse generator 4 to 20 and then 20 While maintaining, the high level output signal is applied to the clear terminal of the first counter 2. The first counter 2 resets the count value according to the high level output signal applied from the second counter 3.

The input and output waveforms of FIG. 1 are shown in FIG.

As shown in the figure, the pulse output according to the user's key input is output after being delayed for a period in which the first counter 2 counts up to 8, and when the key input is turned off (that is, the pulse signal is interrupted), the second counter 3 is output. Resets the first counter 2 after counting to twenty.

As described above, the initial delay circuit of the conventional automatic repeat key uses two counters and an AND gate to add an automatic repeat function. Such a construction method has a cause of malfunction due to the cost of parts required and external noise.

The present invention has been made to solve the above problems, the object of the present invention is to provide a more stable operation and cost reduction of the system to which the initial delayed automatic repeat function is applied by eliminating the cost burden and malfunction factors of parts.

1 is an initial delay circuit of a conventional automatic repeat key.

2 is a waveform diagram illustrating the operation of FIG. 1.

3 is an initial delay processing flowchart of an automatic repeat key according to the present invention.

4 is a block diagram of an initial delay circuit of an automatic repeat key according to the present invention.

Explanation of symbols for main parts of the drawings

1, 11: keyboard 2: 1st counter

3: second counter 4: pulse generator

5: AND gate 6, 16: microcomputer

The initial delay circuit of the automatic repeat key for achieving the above object comprises a first determination step of determining a keyboard for outputting a pulse signal of a predetermined period and the presence or absence of the input pulse signal when the input terminal is kept on; A first counting step of counting by own rounding in units of the period when the pulse signal is not input for a predetermined time period; A second determination step of determining whether the value counted in the first count step is a predetermined value when the pulse is input; A second counting step of counting the number of pulse signals from zero when the value counted in the first count step is equal to or greater than the predetermined value; A third counting step of continuously counting the number of pulse signals when the value counted in the second determining step is less than the predetermined value; A third determining step of determining whether the value output in the third counting step is equal to or greater than a value set for the initial delay of the auto-repeat function; An execution step of outputting the pulse signal to a built-in signal processor when the value is equal to or greater than the set value in the third determination step; And a delay step of not outputting the pulse signal to the signal processing unit when the value is less than the set value in the third determination step.

The initial delay circuit of the automatic repeat key according to the present invention does not require a separate counter or the like by processing a pulse signal applied according to a program stored in a memory element of a microcomputer.

Hereinafter, an initial delay circuit of another auto repeat key will be described in detail with reference to the accompanying drawings.

3 is a signal processing flow chart of a microcomputer, and FIG. 4 is a block diagram of an initial delay circuit of an automatic repeat key.

Referring to the drawings, the first and second variables corresponding to the pulse signals output from the keyboard 11 and input to the microcomputer 16 are performed according to the processing procedure of the program stored in the memory element. Here, the pulse signal is represented by the first variable X, and the absence of the pulse signal by the second variable Y.

In the first determination step 101, it is first determined whether a pulse signal is present. When there is no pulse signal, the second variable value is increased by one digit (first count step 102), and when there is a pulse signal, it is determined whether the second variable value is 20 or more (second determination step (step 103)). In the second count step 104, if the second variable value is 20 or more, the first variable is reset to zero. In the third counting step (step 105), if the second variable value is less than 20, the first variable value is raised by one digit (step 105). In the third judging step (106), it is determined whether the first variable value is 8 or more. If the first variable value is 8 or more, the pulse signal of the input key is output to the signal processor (not shown). A process for executing the command corresponding to the pulse signal is executed (step 107), and if the value of the first variable is less than 8, a delay step (step 108) is delayed by delaying the execution of the pulse signal by resetting the second variable to zero. Rough This process is repeated from the first judgment step of determining the presence or absence of the pulse signal again.

The determination reference values 8 and 20 of the first and second variables set above are just one example, and various setting values are possible in relation to a signal processing speed.

During each step, the execution of the command corresponding to the pulse is delayed until the input pulse reaches 8 or more.

By embedding a program in a memory device (not shown) included in the microcomputer itself as described above, the pulse signal applied from the keyboard can be implemented to have an initial delayed repetition function, thereby reducing the number of components that perform the initial delayed automatic repeat function. In addition, the assembly cost and production cost can be reduced.

This cost reduction comes from the fact that industrial equipment to which the function of the auto delay key is delayed can use this central control unit because it has its own central control unit (including a microcomputer).

As described above, by providing the initial delay circuit of the automatic repeating key according to the present invention, a separate counter or the like is not required by the pulse signal processing applied according to a program stored in a memory device of a microcomputer. Becomes simpler.

Claims (1)

A keyboard for outputting a pulse signal of a certain period when the input terminal is kept on; A first determining step of determining whether the pulse signal is input; A first counting step of counting by own rounding in units of the period when the pulse signal is not input for a predetermined time period; A second determination step of determining whether the value counted in the first count step is a predetermined value when the pulse is input; A second counting step of counting the number of pulse signals from zero when the value counted in the first count step is equal to or greater than the predetermined value; A third counting step of continuously counting the number of pulse signals when the value counted in the second determining step is less than the predetermined value; A third determining step of determining whether the value output in the third counting step is equal to or greater than a value set for the initial delay of the auto-repeat function; An execution step of outputting the pulse signal to a built-in signal processor when the value is equal to or greater than the set value in the third determination step; A delay step of not outputting the pulse signal to the signal processor when the value is less than the set value in the third determination step; and a microcomputer having a memory element having a program stored therein. Initial delay circuit.