JP5107571B2 - LED control method - Google Patents

Description

The present invention relates to an LED control method for simultaneously lighting a plurality of multicolor LEDs with a built-in lighting circuit configured to repeat lighting in a predetermined color order from a predetermined start color to a predetermined end color by power reset.

As an electronic device incorporating an LED control circuit, there is an electronic device described in Patent Document 1 (hereinafter referred to as “conventional electronic device”). Conventional electronic devices have a light transmissive panel with characters, figures, etc. engraved on the surface, and multi-color LEDs are arranged along the length of the bottom of the panel. It is configured so as to enter the panel from above and light up the characters, figures and the like.
Japanese Patent Laying-Open No. 2006-30924 (see paragraph 0004, FIG. 2)

There are at least two types of multicolor LEDs, sometimes called full-color LEDs, a multicolor LED having a built-in lighting circuit and a RGB independent multicolor LED having no built-in lighting circuit. The former is configured to repeat lighting from a predetermined start color to a predetermined end color in a predetermined color order by power reset. In the case of a multicolor LED with a built-in lighting circuit, the lighting repetition is due to the operation of the built-in lighting circuit, while in the case of an RGB independent multicolor LED, it is due to control by an external control circuit. The present invention is directed to this lighting circuit built-in multicolor LED. Therefore, the following description assumes a multicolor LED with a built-in lighting circuit unless otherwise specified. Under this premise, problems to be solved by the invention will be described. That is, even when the lighting cycle from the start of lighting of the predetermined start color to the end of lighting of the predetermined end color is the same rating, there is very little coincidence when compared among a plurality of multicolor LEDs. That is, there are irregular lighting cycles. Variations in elements and lighting circuits, differences in the amount of heat generation, and differences in ambient temperature are common causes of uneven lighting cycles. Suppose that a multicolor LED was used to indicate, for example, a mobile phone call or call. If used in a mobile phone, the number of multicolor LEDs is usually one. Since there is no multi-color LED as a comparison partner that lights at the same time, there is almost no problem with the lighting cycle. On the other hand, for example, in a device in which a large number of multicolor LEDs are turned on at the same time, such as the above-described conventional electronic device, mismatching of lighting cycles may be a problem. That is, when the degree of unevenness is high, when a large number of multicolor LEDs have to light a certain color (for example, “red”) at the same time, any one of the multicolor LEDs is other than red. If the color (for example, “white”) is lit, if the number of multi-color LEDs that illuminate different colors or the ratio to the total becomes excessive, spots or unevenness will occur in the overall lighting color, or the desired red The inconvenience of appearing in a different color occurs. Such a color difference is caused by accumulation of deviations in the period (lighting cycle) from the start of lighting of the predetermined start color of the multicolor LED to the end of lighting of the predetermined end color, and the accumulated deviation exceeds the lighting time for one color. It happens when The uneven lighting cycle described above may be eliminated by the control as long as each multicolor LED can be individually controlled like the above-described RGB independent multicolor LED. Such individual control complicates the control circuit but is also expensive. The problem to be solved by the present invention is to solve the above-mentioned problems. That is, it is a problem to be solved by the present invention to provide an LED control method capable of simultaneously lighting a large number of multicolor LEDs while being inexpensive and without requiring a complicated control circuit.

In order to solve the above problems, the inventor repeats lighting of a multicolor LED from a predetermined start color to a predetermined end color in a predetermined color order by power reset including initial lighting (turning on the power after turning off the power once). In other words, attention was paid to the point that, by resetting the power supply during lighting, the lighted color is extinguished and lighting is resumed from a predetermined start color. Using this point, the end of the lighting cycle in a multicolor LED group with uneven lighting cycles is determined in advance, and the power is reset after the end of the lighting cycle. This is because the lighting color of the multi-color LED is uniformly returned to the predetermined start color by the power reset, and the accumulation of the irregularity of the lighting cycle (displacement) is eliminated by this return. The present invention has been made based on the above-mentioned attention. The details will be explained anew in the section. It should be noted that interpretations and definitions of terms used to explain the invention described in any claim are applicable to the invention described in other claims as long as possible in nature , regardless of the description order of the invention. Shall be.

(Characteristics of the invention of claim 1 )
LED control method according to the invention of claim 1 wherein (hereinafter, appropriately referred to as "control method according to claim 1") is configured to repeat the lighting up to the predetermined end color in a predetermined color order from a predetermined start color by power reset This is a control method for simultaneously lighting a plurality of LEDs of the same type in a multicolor LED with a built-in lighting circuit. According to the control method of the first aspect , the power is reset when a predetermined reset time has elapsed after the power is reset . Further, when the number of multicolor LEDs to be simultaneously turned on is n, the lighting cycle from the start of lighting of the predetermined start color to the end of lighting of the predetermined end color of each of the multicolor LEDs is represented by T1 to Tn. In addition, when the shortest lighting cycle among the lighting cycles T1 to Tn is Tmin, the longest lighting cycle is Tmax, and the reset time is Rt, the relationship is Tmin <Rt <Tmax. Set.
Then, the n multicolor LEDs are selected in advance so that a relationship of Tmin <Rt <Tmax is formed.

According to the control method of the first aspect , the lit multi-color LED group turns off the color that has been lit by the power reset, and is lit again from the predetermined start color. That is, for example, for a multi-color LED having red as a predetermined start color, for example, when the power is reset while white is lit, the white that has been lit is turned off and red is lit. Thus, even if there is some irregularity in the lighting cycle, the lighting color at that time is turned off at a certain time (preferably, when the predetermined end color immediately before returning to the predetermined start color is lit). By uniformly returning to the predetermined start color where no deviation has occurred yet, it is possible to eliminate the deviation due to the irregularity that has occurred at a certain point of time without accumulating. Due to the elimination of misalignment, at least in the specified starting color, the lighting color is uniform and without causing the inconvenience that the colors of the multicolored LEDs that are lit at the same time are uneven or uneven, and that colors other than the desired color are mixed. Can be obtained. According to the control method of the first aspect , it is not necessary to perform complicated control for individually controlling each multicolor LED. Also, since there is a reset time between the longest lighting cycle and the shortest lighting cycle, all the colors that can be lit by each multicolor LED can be lit once in each lighting cycle. it can. That is, if the reset time is shorter than the shortest lighting cycle, for example, the power is not reset without turning on the predetermined end color. On the other hand, if the reset time is longer than the longest lighting cycle, for example, when the trigger signal is issued after the lighting cycle has been cycled and the predetermined start color is re-lighted, at least the predetermined start color is included in one lighting cycle. It will light up twice. In any case, when the entire lighting color is viewed, it may not be a smooth color change. By setting the reset time in the above range, the above-mentioned inconvenience can be avoided.

(Characteristics of the invention described in claim 2 )
In the LED control method according to the second aspect of the invention (hereinafter referred to as “the control method of the second aspect ” as appropriate), as a preferred aspect of the control method of the first aspect, the selection of the multicolor LEDs is performed by image processing. Good.

According to the control method of the second aspect , since the multicolor LED is selected by image processing, it can be accurately selected in a shorter time than at least visual selection.

(Characteristics of Claim 3 )
In the LED control method according to the invention described in claim 3 (hereinafter, referred to as “control method of claim 3 ” as appropriate), as a preferable aspect in the control method of claim 1, a predetermined one of the lights that are simultaneously turned on is predetermined. The detection may be performed by determining whether or not the detection level of the specific color component obtained by each light receiving element exceeds a predetermined level through a color filter that mainly transmits the specific color component.

According to the control method of the third aspect , since only a specific color component (for example, “red component”) that has passed through the color filter passes through the color filter, it is determined as a determination target. The determination accuracy can be increased as compared with the case where the color is a determination target. When the “red component” is a specific color component as in the above example, three colors of yellow, pink, and white are colors including the specific color component in addition to red as viewed with the naked eye.

According to the LED control method of the present invention, complicated control for individually controlling each multicolor LED is not required. In addition, a large number of multicolor LEDs can be turned on simultaneously.

An embodiment of the present invention (hereinafter referred to as “this embodiment” as appropriate) will be described with reference to the drawings. FIG. 1 is a perspective view of an electronic apparatus (illumination device) incorporating an LED control circuit for carrying out the LED control method according to the present invention . FIG. 2 is a right side view of the electronic device shown in FIG. FIG. 3 is a schematic perspective view of the image type selection device. FIG. 4 is a diagram illustrating the operation principle of the image type selection device. 5 and 6 are block diagrams of the light receiving element type sorting apparatus. FIG. 7 is a graph showing an output waveform of the light receiving element type sorting apparatus. FIG. 8 is a perspective view of an electronic device incorporating an LED control circuit according to a modification of the present embodiment.

(Schematic structure of LED control circuit)
With reference to FIG. 1, a schematic structure of an LED control circuit according to the present embodiment (hereinafter referred to as “control circuit” as appropriate) will be described. The control circuit 1 is suitable for implementing the LED control method according to the present embodiment. The control circuit 1 is a circuit for simultaneously lighting a plurality of multi-color LEDs 9 of the same type (also referred to as “multi-color LED group 9”), and includes a drive circuit 3, a timer 5, Is schematically configured. The drive circuit 3 is schematically configured by a power supply unit 3P and a control unit 3C, and the multicolor LED group 9 can be simultaneously turned on and off by the control of the control unit 3C. Turning on and off can be repeated, and turning off the multi-color LED group 9 that is turned on at the same time and then turning it on again is referred to as “power reset” in this specification. The controller 3C is configured to wait for the trigger signal Ts and cause the drive circuit 3 to reset the power. The trigger signal Ts is output by the timer 5. The timer 5 has a function of outputting the above-described trigger signal Ts, and this trigger signal Ts is set to be output every elapse of a predetermined reset time Rt. Specifically, the control unit 3 </ b> C and the timer 5 are configured by a microcomputer 7. An external computer (not shown) or the like can be used instead of the microcomputer. The reset time Rt is determined based on the multicolor LEDs 9 to be controlled,. The lighting cycle T will be described in detail in the next section.

(Structure of multi-color LED)
The multi-color LED 9 is an LED with a built-in lighting circuit configured to repeat lighting from a predetermined start color to an end color in the predetermined color order upon power reset. Sometimes called full-color LED. Each multi-color LED has a lighting cycle T from the start of lighting of a predetermined start color to the end of lighting of a predetermined end color, and this lighting cycle T almost coincides even between multi-color LEDs of the same type. Not. That is, they are not uniform. Here, if there are 1, 2,... N multicolor LEDs 9,..., It can be said that there are lighting periods of T1, T2,. Each of the multicolor LEDs 9 employed in the present embodiment is configured to be repeatedly lit in the order of red → green → blue → yellow → light blue → pink → white after power reset. The predetermined start color is red and the predetermined end color is white. The lighting time of each of the seven colors is approximately 4 to 6 seconds for each color, and therefore the lighting cycle of the multicolor LED 9 is approximately 40 seconds.

  As described above, the lighting period T of the multicolor LED 9 adopted in the present embodiment is about 40 seconds, but the inventors have actually measured about 20 of the same type of multicolor LED 9,. There was a lighting cycle that exceeded 4 seconds between the shortest and longest. As a specific example, while one multicolor LED 9 is lit white, which is a predetermined end color, the other multicolor LED 9,... Finishes white lighting and lights red in the next lighting cycle. Occurs. Such color misregistration causes color spots or the like for simultaneous lighting of the multicolor LED group 9, and therefore it is preferable to eliminate it as much as possible. For this purpose, there is a method of suppressing the unevenness of the lighting periods T1 to Tn of the n multi-color LEDs 9,. Specifically, by the multi-color LEDs 9,... Having a correlation such that a predetermined end color in the longest lighting cycle Tmax starts to be turned on before the shortest lighting cycle Tmin of the lighting cycles T1 to Tn ends. What is necessary is just to comprise the multicolor LED group 9. FIG. In the present embodiment, multi-color LEDs to be controlled by the control circuit 1 are selected based on the above-mentioned purpose. The reset time Rt when the selected multicolor LED group 9 is controlled by the control circuit 1 is set to satisfy Tmin <Rt <Tmax. Among T1 to Tn, Tmin is the shortest lighting cycle, and Tmax is the longest lighting cycle. If the above setting is performed on the premise of selection, the above-described inconvenience that the lighting of the predetermined start color starts in the subsequent lighting cycle before the lighting of the predetermined end color starts in the preceding lighting cycle. This is because it can be avoided. A multicolor LED sorting method and sorting apparatus will be described later.

(Functions and effects peculiar to the present embodiment)
According to the control circuit 1, the multi-color LED group 9 that is turned on when the power is turned on turns off the color that has been turned on by the power reset and starts again from the predetermined start color. That is, for a multi-color LED having red as a predetermined start color, for example, if the power is reset while white is lit, the white that was lit is turned off and red is lit. The above example will be described more specifically. For example, it is assumed that when a certain multicolor LED 9 finishes turning on white and starts turning on red in the next cycle, another multicolor LED 9 is still lighting white. Here, when the power is reset, the former multicolor LED 9 lit in red turns off the lit red and starts (restarts) red lighting, while the latter multicolored LED 9 lit in white The LED 9 turns off the lighted white and starts to light red simultaneously with the start of the former red lighting. By the simultaneous lighting of red, the deviation of the lighting cycle between the two parties is eliminated. The power of the multicolor LED group is supplied by the drive circuit 3, and the power supply reset is performed by the drive circuit 3 when the drive circuit 3 receives the trigger signal Ts from the timer 5. According to the control by the control circuit 1, when the lighting cycle is very uneven, the trigger signal Ts is output before any one of the seven colors (for example, “white”) is turned on, Although white is lit in the above example, the trigger signal Ts may be output while the lighting time is extremely short. However, by resetting the power supply, accumulation of irregular lighting cycles is prevented, which keeps the lighting colors uniform. The control circuit 1 is an extremely inexpensive circuit because it does not require a complicated control circuit for individually controlling the individual multicolor LEDs 9.

(Application example of LED control circuit)
An electronic device including the control circuit 1 described above will be described. Reference numeral 101 in FIGS. 1 and 2 indicates a lighting device which is an example of an electronic apparatus. The illuminating device 101 has a light transmissive panel 103 engraved with characters, figures, etc. (indicated by reference symbol G) on its surface, and is placed on a base 102. A multicolor LED 9,... Are arranged so that the light of the multi-colored LEDs that are lit at the same time enters the panel from the bottom and lights up the characters, figures, and the like. The multicolor LEDs 9,... Are controlled to be turned on simultaneously by the built-in control circuit 1. The control circuit 1 is incorporated in a substrate 105 to which multicolor LEDs 9... Are attached, and the substrate 105 is built in the base 102. The above-described lighting device is an example of an electronic device including a control circuit, and a device that includes the control circuit and simultaneously turns on a plurality of multicolor LEDs corresponds to the electronic device according to the present invention. To do. For example, a control circuit is also incorporated in a device that lights a lamp or illumination composed of a large number of multicolored LEDs, and an illumination lamp connected with an electric wire to decorate a Christmas tree. This apparatus is a typical example of the electronic apparatus.

(Multicolor LED sorting method)
A specific sorting method for multicolor LEDs will be described. For example, there are the following two types of multicolor LED selection methods (hereinafter simply referred to as “selection methods”) employed in the present embodiment. The first sorting method is a sorting method based on image processing using a CCD camera, and the next sorting method is a sorting method in which sorting is performed using a light receiving element. Hereinafter, it demonstrates in order.

(Selection method by image processing)
Based on FIGS. 3 and 4, an LED sorting device (hereinafter simply referred to as “image type sorting device”) that sorts multi-color LEDs by image processing will be described. The image type sorting device 21 has a plurality of sockets (connection structure) 23 (socket group 2) for detachably connecting each of the multicolored LEDs 9 to be sorted, and each multicolored LED 9 to be sorted via the socket group 23. By analyzing a drive power supply 25 capable of supplying power simultaneously, a CCD camera (photographing means) 27 for photographing the LED group 9 to be lit, and a photographed image photographed by the CCD camera 27, And a computer (analyzing means) 29 for analyzing the lighting cycle of each LED. Each socket constituting the socket group 23 is fixed to the socket substrate 22, and each socket is arranged in a grid and connected in parallel. The reason why they are connected in parallel is to enable simultaneous supply of power to each of the multicolor LEDs 9 to be selected. The computer 29 also has a function of controlling the drive power supply 25.

  The selection method of multicolor LED by the image processing using the image processing device 21 is as follows. First, as shown in FIG. 3, a plurality (25 in this embodiment) of the multicolor LEDs 9 to be selected are inserted into the socket group 23 and arranged in a grid pattern. Next, the camera 27 is installed at a position where the grouped multicolor LED group can be photographed at once. Although not shown in FIG. 3, it is preferable that the CCD camera 27 is not moved by using a fixed stand or the like. Here, the driving power source 25 is driven to turn on the multicolor LEDs 9 to be sorted at the same time, and photographing by the CCD camera 27 is performed. Photographing is performed until each of the multicolor LEDs 9 to be selected ends at least one lighting cycle T. The captured image of the CCD camera 27 is captured by the computer 29 and analyzed.

  That is, the captured captured image is displayed in each of a plurality of frames F1 to Fn created based on a preset frame rate (frame interval). Here, the image displayed in each of the frames F1 to Fn is analyzed while paying attention to the wavelength of a predetermined specific color component (here, “red component”). That is, in addition to the red component of red itself, a color filter (not shown) that mainly passes the red component included in the three colors of yellow, pink, and white is arranged between the multi-color LED 9,. In this embodiment, a method of setting (extracting) a specific color component using image analysis software installed in the computer 29 is employed. The analysis will be described more specifically. First, attention is focused on the multicolor LED (D1) and the multicolor LED (D2) shown in FIG. Both graphs shown on the right side of FIG. 4 correspond to the multicolor LED (D1) and the multicolor LED (D2), respectively, and the horizontal axis represents the period, and the vertical axis represents the specific color component digitized. It is. That is, the vertical axis represents the High signal when the level of the specific color component is compared with a predetermined threshold and the threshold is exceeded, and the Low signal is digitally displayed when the threshold is not exceeded. First, a multicolor LED (D1) will be described as an example. The multicolor LEDs (D1) on the frames F1 and F2 indicate red, but on the frame F3, colors other than red (for example, “green”) are illustrated. Therefore, it is shown that a red component (at a level exceeding the threshold) is detected in the part of the graph D1 corresponding to the frame F1 and the frame F2, but is detected in the part corresponding to the frame 3 Is not shown. Further, red is also shown on the frame Fn, and when the waveform on the frame F1 is periodically detected, the falling edge of the frame Fn from the time when the waveform on the frame F1 rises. Is grasped as the lighting cycle Td1 of the multicolor LED (D1). For each of the multicolor LEDs (D2) or other multicolor LEDs, the lighting cycle Td2 is grasped by the same method as described above. When the lighting cycles Td1 and Td2 of the grasped multicolor LEDs (D1) and (D2) are compared with each other and the difference exceeds a predetermined range (for example, the lighting time range of each color), You may make it grasp | ascertain which multi-color LED which the multi-color LED which concerns the thing beyond it is. The sorting operation is completed by removing each multicolor LED 9 from the socket 23.

(Selection method by light receiving element)
Based on FIGS. 5 and 6, an LED sorting device (hereinafter simply referred to as “light receiving type sorting device”) that sorts multicolor LEDs using a light receiving element will be described. The light receiving type sorting device 31 has a socket (connection structure) 33 (socket group 33) for detachably connecting each of the multicolored LEDs 9 to be sorted, and a power supply to each of the multicolored LEDs 9 to be sorted via the socket group 33. , A plurality of light receiving elements 37 (light receiving element group 37) arranged so as to be able to individually receive light to be turned on, a plurality of light receiving elements 37 and a plurality of light receiving elements 37 A color filter 39 disposed between the multicolor LED 9 and a determination unit 41 is generally configured. The socket 33 has the same function as the socket 23 described above, and the drive power supply 35 has the same function as the drive power supply 25 described above. The color filter 39 is a filter for allowing the specific color component (here, “red component”) to pass through most. The light receiving elements 37 are arranged so as to correspond to the to-be-selected multicolor LEDs 9 that face each other with the color filter 39 interposed therebetween. The lighting color (color including the red component) of the multicolor LED 9 to be sorted passes through the color filter 39 and is received by the corresponding light receiving element 37. The light receiving element 37 that has received the light converts this into an electric signal and outputs it. The reason for providing the color filter 39 is to simplify the electrical signal (detection signal) output from the light receiving element 37 by narrowing down the color component received by the light receiving element 37 to a specific color component, thereby facilitating determination. It is. That is, if the color filter 39 is not provided, electrical signals are output for colors including components other than the red component in the above example, for example, green and blue, and the electrical signals are continuously output. If the electric signal continues to be output, the lighting start point and the lighting end point cannot be accurately determined, so that the lighting cycle is not accurately determined. Therefore, a color filter 39 is provided so that the lighting start point and lighting end point of the selected reference color can be accurately determined. The determination unit 41 includes a conversion unit 43, a determination unit 45, a communication control device 47, and a computer 49.

  The conversion unit 43 and the determination unit 45 will be described with reference to FIG. The conversion unit 43 is a circuit configured by a resistor R1 and a capacitor C1 connected in parallel, and has a function of easily shaping a complex waveform output from the light receiving element 37 to make a determination. The electrical signal output from the conversion unit 43 is input to the second pin of the comparator 46 that is the main component of the determination unit 45. A reference voltage e is applied to the third pin of the comparator 46, and an output signal is output from the seventh pin. The reference voltage e is obtained by dividing the power supply voltage by the resistors R2 and R3. Here, if the voltage input from the 2nd pin is larger than the reference voltage e, High (the selected reference color is turned on), otherwise, an electrical signal (described in the next section) is output from the 7th pin as Low. It is like that. The output electrical signal is input to the computer 49 via the communication control unit 47, where final determination is made.

  The electric signal output from the comparator 46 will be described with reference to the graph shown in FIG. The vertical axis indicates the output voltage, and High indicates that the specific color level received by the light receiving element 37 exceeds a predetermined threshold, and Low indicates that the threshold does not exceed the threshold. Each is a digital display. The horizontal axis shows the passage of time. Here, as described above, the to-be-selected multicolor LED 9 employed in the present embodiment is repeatedly lit in the order of red → green → blue → yellow → light blue → pink → white after the power is reset. Under this premise, the colors other than red and including the red component are three colors of yellow, pink and white. When the four colors including red are included in the three lighting colors, red is not included between yellow and pink (light blue), and thereafter, three colors of pink → white → red are continuous. And red is not included between red and the next yellow (green and blue). In other words, red is included in the time for one color of yellow, and then red is included in the time for three colors with an interval of one color thereafter. Furthermore, red is not included between two colors from red to the next yellow. When this is seen in the graph shown in FIG. 7, there is an interval between P2 and P3, and there is an interval between P4 and P5. Furthermore, the lengths of P2 and P4 are substantially the same, the lengths of P3 and P5 are substantially the same, and this length is approximately three times the length of P2 (P4). Between P1 and P2 and between P3 and P4, both are approximately twice the length of P2 (P4). From this, it can be seen that P2 and P4 are yellow, and P3 and P5 are three consecutive colors of pink → white → red. Since P1 is a signal in the middle of the preceding three colors of pink → white → red, it is not used here. Here, for example, by counting the falling time (voltage change) of P2 to the falling time (voltage change) of P4, that is, by measuring the time until the number of voltage changes (here, 5 times) is counted, The lighting cycle T of the multicolor LED 9 to be sorted is measured. Here, the falling edge of P2 is used as a reference point for counting, but a point arbitrarily selected from other falling or rising edges is set in advance as a reference point. Setting of the reference point is performed by the computer 49 which is a determination means.

  Here, the same-type equivalent multicolor LED groups 9 are simultaneously turned on, the lighting periods T obtained from the corresponding light receiving elements 37 by the above functions are compared, and whether or not the difference falls within a predetermined range. Is determined by judging. The sorting operation is completed by removing each multicolor LED 9 from the socket 33.

(Modification of this embodiment)
The control circuit 1 according to this embodiment described above has the timer 5 as an output source of the trigger signal Ts. Instead of the timer 5, the control circuit 1 'according to this embodiment includes a detection circuit 55 as shown in FIG. There is no difference between the other parts. The detection circuit 55 is configured to select one of the multi-color LED groups 9 and output the trigger signal Ts after waiting for the lighting of a predetermined end color of one (multiple or all) of the multi-color LEDs 9. It is. The detection of the predetermined end color can be performed by, for example, a sorting device using a light receiving element shown in FIG. Since the predetermined end color of the multi-color LED 9 is white (having all the RGB components), there is a method in which the multi-color sensor is used as a light receiving element by omitting the color filter if it is difficult to become familiar with the filtering by the color filter. There is no difference between the control circuit 1 ′ and the control circuit 1 except that the trigger signal output source is different.

It is a perspective view of the electronic device (illuminating device) which incorporates an LED control circuit. It is a right view of the electronic device shown in FIG. It is a schematic perspective view of an image type selection apparatus. It is a figure which shows the principle of operation of the image side selection apparatus. It is a block diagram of a light receiving element type sorting apparatus. It is a block diagram of a light receiving element type sorting apparatus. It is a graph which shows the output waveform of a light receiving element type | mold selection apparatus. It is a perspective view of the electronic device which incorporates the LED control circuit which concerns on the modification of this embodiment.

1, 1 'LED control circuit 3 Drive circuit 5 Timer 7, 29, 49 Computer 9 Multicolor LED (group)
21 Image Sorting Device 22, 32 Socket Board 23, 33 Socket Group 25, 35 Drive Power Supply 27 CCD Camera 39 Color Filter 55 Detection Circuit

Claims (3)

In the LED control method for simultaneously lighting a multicolor LED with a built-in lighting circuit configured to repeat lighting from a predetermined start color to a predetermined end color in a predetermined color order by power reset,
There line power reset when predetermined reset time after power reset has elapsed,
When the number of multicolor LEDs to be simultaneously turned on is n, the lighting cycle from the start of lighting of the predetermined start color of each multicolor LED to the end of lighting of the predetermined end color is T1 to Tn, And, when the shortest lighting cycle among the lighting cycles T1 to Tn is Tmin and the longest lighting cycle is Tmax,
When the reset time is Rt, Tmin <Rt <Tmax is set to satisfy the relationship,
An LED control method, wherein the n multi-color LEDs are selected in advance so that a relationship of Tmin <Rt <Tmax is formed . Sorting multicolor LED in the LED control method according to claim 1, wherein the performing by analyzing the captured image obtained by capturing light of the sorted multicolor LED, each obtained by simultaneous lighting claim 1 The LED control method as described. The selection of the multi-color LED in the LED control method according to claim 1 is received by the light receiving element through a color filter that mainly transmits a predetermined specific color component among the simultaneously lit lights, and each of the light receiving elements 2. The LED control method according to claim 1 , wherein the LED control method is performed by determining whether or not the detection level of the specific color component obtained has exceeded a predetermined level.

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