KR100194410B1 - How to adjust the display lamp brightness of the phone - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a method of adjusting the brightness of a display lamp of a phone having a curved surface, and more particularly to a method of controlling the lighting time of a display lamp mounted at a different surface by controlling the lighting time according to the position. It is about.

2. The technical problem to be solved by the invention

Since the time to turn on the display lamps with different positions mounted on the phone is the same, the display lamp at the lower part which adjusts the brightness by inserting a resistor in order to have the same light brightness in appearance is absolutely lacking in the lighting time. There was a problem that could not be adjusted.

3. Summary of Solution to Invention

The present invention provides an apparatus and method for adjusting the appropriate brightness by designating a group for each position on which a display lamp of a curved part of a telephone is mounted and adjusting a lighting time.

4. Important uses of the invention

How to adjust the brightness of the indicator lamp on the telephone.

Description

How to adjust the display lamp brightness of the phone

1 is a perspective view of a telephone generally equipped with an indicator lamp.

2 is a circuit diagram of a display lamp brightness control device of a typical telephone.

3 is a diagram showing the installation of a display lamp generally mounted on a telephone.

4 is a timing diagram for turning on a display lamp of a conventional telephone.

5 is a timing diagram for turning on the display lamp of the telephone according to the present invention.

6 is a flowchart for controlling the lighting time of the display lamp of the telephone according to the present invention.

* Explanation of symbols for main parts of the drawings

10: CPU 20: LED Matrix

The present invention relates to a method of adjusting the display lamp light brightness of a phone having a curved surface, and in particular, to control the lighting time by controlling the lighting time according to the position of the lighting of the mounted display lamps having different positions on the curved parts. It is about how to.

In general, the phone is equipped with an indicator lamp to indicate any state, which is convenient for the user to check. However, these days, the telephone has become more versatile and the number of the display lamps becomes more and more complicated.

In the conventional curved telephone, the display lamp of Group B is located at the upper end of the main body with the distance of L1 (distance between the main body and the substrate) from the substrate on which the display lamp is mounted as shown in FIG. 1, and L2 at the lower end of the main body. The display lamp of group A is located with the distance between the body and the board. The circuit for operating the mounted display lamp as described above is the same as in Figs. 2 and 3, and the waveform diagram showing the operation state thereof is as in Fig. 4. Therefore, when the strobe signal for controlling the LED matrix 20 from the CPU 10 is applied high and the data signal for turning on the LED lamp is applied low, the corresponding LED lamp of the LED matrix 20 is turned on. At this time, the strobe signal is applied for one period (time of one cycle is about 60 Hz or more as a time when an ordinary person causes an optical illusion) sequentially from strobe 1 to strobe 4, and then synchronized with the strobe signal. The corresponding data signal is applied to light the corresponding LED lamp. Then, the LED lamp is turned on and blinks continuously while displaying any state. However, the flickering of the LED lamp is operated so that it is difficult to determine with the naked eye.

However, in the operation of the conventional LED lamp as described above, in the case of a telephone having a curved surface, the position where the display lamp is mounted is different from the circuit board, and thus the difference in brightness is shown. Therefore, in order to compensate for this, in the past, the same luminosity was displayed in appearance by adjusting the current for each position. For example, when the L1 lamp and the L2 lamp are turned on, the waveform diagram of FIG. 4 will be described in more detail.

First, when the count of the strobe signal is 1, the CPU 10 applies a high signal to the output port of the strobe 1 by T1 time. At this time, the CPU 10 applies the low signal to the data signal output port D ₀ by the time of T1 in accordance with the time of the output strobe signal. Therefore, the LED1 lamp of the LED matrix 20 is turned on by T1 time. Then, after the T1 time has elapsed, the output port of the strobe 1 is restored to the data output port D ₀ high and the LED1 lamp flashes. The CPU 10 then increments the count of the strobe signal by one. At this time, when the count of the strobe signal is 2, the CPU 10 applies a high signal to the output port of the strobe 2 for a time T1, and keeps all the ports of the data output high to maintain the LED matrix 20. Keep LED1 lamp blinking. Then, after the T1 time has elapsed, the output port of the strobe 2 is reset to low, and the count of the strobe signal is increased by one. At this time, when the count of the strobe signal is 3, the CPU 10 applies a high signal to the output port of the strobe 3 for a time T1, and keeps all the ports of the data output high to keep the LED matrix 20 of the LED matrix 20. Keep LED1 lamp blinking. Then, after the T1 time has elapsed, the output port of the strobe 3 is reset to low, and the count of the strobe signal is increased by one. At this time, when the count of the strobe signal is 4, the CPU 10 applies the high signal to the output port of the strobe 4 for T1 time and the low signal to the data signal output port D ₃ for the T1 time. . Therefore, the LED12 lamp of the LED matrix 20 is turned on by T1 time. Then, after the T1 time has elapsed, the output port of the strobe 4 is restored to the data output port D ₃ high and the LED 4 lamp flashes. Thereafter, the CPU 10 resets the count of the strobe signal to finish one cycle and repeatedly operates the next cycle as described above.

Since the time to turn on the display lamps with the different mounted positions is the same, the display lamp at the bottom of the lower part where the brightness is adjusted by inserting a resistor in order to have the same light brightness in appearance is absolutely short of the lighting time. There was a problem that the brightness can not be adjusted.

Accordingly, the present invention provides a method for adjusting the appropriate brightness by designating a group for each position on which a display lamp of a curved portion of a telephone is mounted and adjusting a lighting time.

In order to achieve the above object, the present invention provides a method for adjusting the display lamp light brightness of a telephone having a display lamp matrix for lighting the display lamp through a strobe signal output port and a data signal output port in a plurality of columns and rows. Designating a display lamp located on an outer case of the phone as a predetermined group, and setting a lighting time of the display lamp located on a lower part of the phone to a predetermined time larger than a lighting time of the display lamp located on an upper part of the outer case of the phone; When a strobe signal and a data signal are input for operating the corresponding display lamp of the display lamp matrix, turning on the corresponding display lamp and detecting which group the lit display lamp corresponds to; According to the display lamp lighting time set in the relevant group of the display lamp It characterized by a process constituted by any of lighting the indicator lamp.

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

FIG. 1 is a perspective view of a telephone generally equipped with a display lamp, wherein the group mounted on the upper end of the telephone having a distance between the substrate and the main body is L1 and the group B is mounted on the lower end of the telephone having a distance between the substrate and the main body being L2. Make group A group.

2 is a circuit diagram of a display lamp brightness control device of a general telephone, including a CPU 10 for generating a control signal for generating a strobe signal and a data signal to light a desired display lamp, and the control generated from the CPU 10. It consists of an LED matrix 20 that receives the signal and turns on this lamp.

3 is a configuration diagram of a display lamp mounted on a telephone in general, and when the strobe signal generated from the CPU 10 is high and the data signal is applied low, the display lamp is turned on.

4 is a timing diagram for turning on the display lamp of the conventional telephone.

5 is a timing diagram for turning on a display lamp of a telephone according to an embodiment of the present invention, wherein one cycle of the timing diagram is generally 60 Hz or more, which is a time when a human is causing an optical illusion and the lamp is continuously lit. . Then, Ta, which is the time for turning on the lamp of group A, is adjusted to be longer than Tb, which is the time for turning on the lamp of Group B, to give sufficient lighting operation time.

FIG. 6A is a flowchart for controlling the lighting time of the telephone display lamp according to the present invention. FIG. 6A shows a high signal at the strobe 1 output port, and applies the data output port of the lamp to be turned on as a low signal for a predetermined time. A control flow chart for increasing the counter of the strobe 1 signal by operating (Ta) and resetting the strobe 1 output port to a low state. FIG. 6b is a high signal to the strobe 2 output port when the strobe counter is increased by 1. Then, by applying the data output port of the lamp to be turned on as a low signal to operate the lamp for a predetermined time (Ta), and reset the output port of the strobe 2 to a low state, the control to increase the counter of the strobe 2 signal by 1 FIG. 6C is a flow chart showing the high signal to the strobe 3 output port and the lamp to turn on when the strobe counter is increased by one. Is a control flow diagram that applies the output signal to the low signal to operate the lamp for a predetermined time Tb, resets the output port of the strobe 3 to the low state, and increases the counter of the strobe 2 signal by one. FIG. When the strobe counter is increased by 1, a high signal is drawn to the strobe 4 output port, and the data output port of the lamp to be turned on is applied as a low signal to operate the lamp for a predetermined time (Tb), and the output port of the strobe 4 is low. After resetting, the counter for the strobe 4 signal is reset.

Hereinafter, a waveform diagram of FIG. 5 which is an embodiment attached to the present invention and a flowchart of FIG. 6 will be described in detail.

First, in step 600, the CPU 10 detects whether the state of the strobe counter is one. At this time, when the state of the strobe counter is 1, in step 602, the CPU 10 applies the output port of the strobe 1 as a high signal, and simultaneously applies a data signal through each data output port to turn on the corresponding lamp. . At this time, as shown in the waveform diagram of FIG. 5 as an embodiment, L1 of the corresponding lamp is turned on by applying the output of the data output port D ₀ as a low signal. Then, in step 604, the CPU 10 detects whether the counter Ta of the lamp lighting time check timer has been reached. At this time, when the lamp lighting time check timer does not become Ta, the CPU 10 increments the counter of the check timer by 1 and performs step 604 again in step 606. However, when the ramp-on time check timer becomes Ta, the CPU 10 resets the check timer to 0, the strobe output port to the low state, and the data output port to the high state in step 608. Then, in step 610, the CPU 10 increases the strobe counter by one and feeds back to step 600 to detect whether the strobe counter is 1 again. At this time, when the strobe counter is not 1, the CPU 10 detects whether the strobe counter is 2 in step 612. At this time, when the state of the strobe counter is 2, in step 614, the CPU 10 applies the output port of the strobe 2 as a high signal, and simultaneously applies a data signal through each data output port to turn on the corresponding display lamp. Let's do it. At this time, as shown in the waveform diagram of FIG. 5, the display lamp maintains the flashing state by applying the outputs of all the data output ports as high signals. Then, in step 616, the CPU 10 detects whether the counter of the display lamp lighting time check timer is Ta. At this time, when the display lamp lighting time check timer does not become Ta, in step 618, the CPU 10 increases the counter of the check timer by one and performs step 616 again. However, when the lamp lighting time check timer becomes Ta, the CPU 10 resets the check timer to 9 and the strobe output port to a low state in step 620. Then, in step 622, the CPU 10 increments one strobe counter and feeds back to step 612. When the strobe counter is not 2, the CPU 10 detects whether the strobe counter is 33. . If the state of the strobe counter is 3, the CPU 10 applies the output port of the strobe 3 as a high signal in step 626, and simultaneously applies a data signal through each data output port to turn on the corresponding lamp. Let's do it. At this time, as shown in the waveform diagram of FIG. 5 as an embodiment, the lamp maintains the flashing state by applying the outputs of all the data output ports as high signals. Then, in step 628, the CPU 10 detects whether the counter of the lamp lighting time check timer has reached Tb. In this case, when the lamp lighting time check timer does not become Tb, the CPU 10 increments the counter of the check timer by one and performs step 628 again in step 630. However, when the lamp lighting time check timer becomes Ta, the CPU 10 resets the check timer to 0 and the strobe output port to a low state in step 632. Thereafter, in step 634, the CPU 10 increases the strobe counter by one and feeds back to step 624 to detect whether the strobe counter is three again. In this case, when the strobe counter is not 3, the CPU 10 detects whether the strobe counter is 4. At this time, when the state of the strobe counter is 4, in step 638, the CPU 10 applies the output port of the strobe 4 as a high signal and simultaneously applies a data signal through each data output port to turn on the corresponding lamp. . At this time, the L12 lamp is turned on by applying the output of the data output port D3 as a high signal as shown in the waveform diagram of FIG. Then, in step 640, the CPU 10 detects whether the counter of the lamp lighting time check timer is Tb. At this time, when the lamp lighting time check timer does not become Tb, the CPU 10 increments the counter of the check timer by one and performs step 638 again in step 624. However, when the ramp lighting time check timer becomes Tb, the CPU 10 resets the check timer to 0 and the strobe output port to a low state in step 644. Then, in step 646, the CPU 10 resets the strobe counter and feeds back to step 600 to detect whether the strobe counter is 1 again.

As described above, by providing a device and a method for adjusting the appropriate brightness by designating a group for each position where the display lamp of the curved part of the telephone is mounted and adjusting the lighting time, it is possible to accurately recognize all the states of the user's telephone. have.

Claims (1)

In a method of adjusting the display lamp light brightness of a telephone having a display lamp matrix for lighting the display lamp through a strobe signal output port and a data signal output port in a plurality of columns and rows, the display lamp located in the outer case of the telephone is predetermined. And setting the lighting time of the display lamp located at the lower end of the display lamp to be larger than the lighting time of the display lamp located at the top of the outer case of the phone by a predetermined time, and operating the corresponding display lamp of the display lamp matrix. When there is an input of a strobe signal and a data signal for the display, turning on the corresponding display lamp and detecting which group the illuminated display lamp corresponds to; and displaying the display lamp set in the corresponding group of the display lamp according to the detection result. The display lamp is turned on by the lighting time. Indicator lamp lights brightness control method of telephone features luggage.