TWI378250B - Light emitting diode alarm system - Google Patents

Description

1378250 IX. Description of the Invention: [Technical Field] The present invention is a warning system and method for a light-emitting diode, and more particularly, a warning system and method for a light-emitting diode having an effective life detection of a light-emitting diode. [Prior Art] • Light Emitting Diode (LED), which has high shock resistance, long life, low power consumption, and low heat generation, so its application range is common in everyday life. Various items, such as household appliances and indicators or light sources of various instruments. In recent years, with the advent of the White Light-Emitting Diode (WLED), LEDs have been used in the past, only in the case of indicator lights, neon lighting, etc., and have begun to move into the field of electronic lighting, including automobiles. Directional auxiliary lights, digital camera flashes, etc., in the future can replace incandescent and fluorescent lights, do the main home lighting. Generally, conventional LEDs are transmitted through a P/N interface. If a defect occurs on the P/N interface, current is easily concentrated and burned. However, after a period of use of the LED, the brightness will gradually decrease. Therefore, it is necessary to increase the current drive so that the brightness of the LED can be maintained, but this increases the probability of burning the LED. In addition, LEDs can only be replaced in the event of damage, and the degree of damage of the LEDs cannot be known in advance, and as a pre-replacement consideration, it is inconvenient and dangerous for the user. For example, all safety components of the vehicle, such as oil quantity and water 1378250

Temperature and airbags, there are almost all indicators on the dashboard, although the lights also have open warning lights, but they are all displayed when the light source is completely disabled, that is, the user may experience the time when the light source is needed but no light source. . If it is born on the number of lights and railway signal lights, the danger is even higher. Existing LEDs:: k traditional light sources, especially LEDs, due to the characteristics of semiconductor materials, the light output is gradually reduced during use, and Depending on the temperature of use and the state of the environment, the true life and light output of each LED cannot be accurately predicted. Generally, all failures occur in use. For general photos, although it is inconvenient, it is acceptable. If the source is used for safety or signal, there is a great danger, such as lights and signal lights and railway lights. SUMMARY OF THE INVENTION The present invention can provide a warning system and method for a light-emitting diode having an effective lifetime detection of a light-emitting diode. The invention can also provide an LED device light source effective life detection lacking system, that is to say, before the brightness of the LED light source is not reduced and completely failed, the warning function of the indicator light or the effective percentage signal of the die is provided. The invention can also provide a warning system for a light-emitting diode, comprising a 'lighting unit, a detecting device and a warning device. The light emitting unit is composed of a plurality of microcrystal grains. The detecting device is configured to detect the lighting unit and output a detection result. The warning device displays a damage state of the microcrystal grains in the light emitting unit according to the detection result. [Embodiment] FIG. 1 is a schematic view showing the structure of an LED microcrystal. The 6 1378250 LED chip shown in Figure 1 can be an AC LED or a high voltage DC LED. On the LED chip, the LED is first divided into dozens of micro-grains and then electrically connected. Therefore, the defect characteristics of the wafer are also completely divided into dozens of blocks, and there is no y-chain effect. When there is a micro-grain failure on the LED wafer, it does not make the entire LED completely illuminate, so the degree of single micro-grain failure will be calculated by taking the total micro-grain number as the denominator. Therefore, the more the micro-grain number is divided, the lower the influence of single micro-grain failure. For example, with an AC LED composed of 36 micro-grain numbers, the single micro-grain failure effect is only 2.7% and the range of influence is very likely. Only in one half of the alternating current. If it is designed in the form of a relatively high voltage, the 'AC LED or the high voltage LED micro • The crystal grain may be more than 100', and each of the micro-grain failure effects will be reduced to 1%. According to the analysis of AC LED failure characteristics, if the current experimental data and the failure criterion are 30%, 1 微 micro-arc AC led is equivalent to 30 micro-crystal failures to reach the failure condition. The output is still higher than the initial brightness, but the efficiency is poor and the 'LED lifetime can be extended from the defect effect _ should be fully extended. Figure 2A is a schematic diagram of the number of failed micro-grains in an AC LED and the voltage-current-power ((V-I_W)) of the AC led. In Fig. 2, an AC LED of -0.06 mm2 36/54 pcs is taken as an example. Curve 21 represents • a fixed AC voltage, curve 22 is the current received by the AC LED, and curve 23 is the power consumed by the AC LED. From Fig. 2A to Fig. 2F, it can be found that the more the number of failed microcrystals, the higher the current received by the AC LED, which also causes the brightness of the light emitted by the AC LED to increase. Although the luminous efficiency of the AC LED will become poor, it can effectively extend the life of the 7 1378250 LED. Such features also appear on high voltage DC LEDs composed of microcrystals. Figure 3 shows the micro-crystal failure of the AC LED driven by a constant voltage - a graph of the rate of change of the characteristic. In Fig. 3, the flow LED of 0.06 mm 2 36/54 pcs is taken as an example. Curve 31 represents a conventional LED failure profile. Since the PN junction of a general LED is defective as long as it is driven by a constant voltage system, the luminous flux and the equivalent internal resistance will drop rapidly, and the current will rise rapidly and burn the LED to form an open circuit. Curve 32 represents the percentage change in input power for different numbers of micro-crystals in the AC LED. Curve 33 represents the percent change in luminous flux of the alternating current LED when a different number of microcrystals in the alternating current LED fails. Curve 34 represents the percentage change in luminous efficiency of the alternating current LED when a different number of microcrystals in the alternating current LED fails. As can be seen from the figure, the higher the number of micro-grain failures, the more the luminous flux emitted by the AC LED. When the number of micro-grain failures in the AC LED is 8, the input power is increased by 159°/. The luminous flux of the AC LED output increased by 53%, and the luminous efficiency decreased by 41.5%. AC LEDs or high-voltage DC LEDs under a constant voltage drive® will have a luminous flux rise interval in the case of partial micro-grain failure short-circuits. This phenomenon is caused by an increase in input power and current and is proportional to the number of micro-grain failures. . At this point, the failure of the AC LED will only reduce its own luminous efficacy. • The rate does not burn like the conventional LED due to the rapid drop in equivalent internal resistance. • If some of the micro-arrays on the AC LED are open, it is also possible to maintain a half-wave amount (that is, the AC LED will still emit light when the AC voltage is in the positive or negative voltage range). Because the AC LED or high-voltage DC LED proposed by the present invention fails in the partial 1378250 micro-die, the luminous flux of the output increases, so if the luminous flux of the AC LED or the output to the DC LED is fixed, it is necessary to be in the AC LED or When the luminous flux of the high-voltage DC LED output increases, the voltage or current of the input-AC LED or the high-voltage DC LED is reduced. It is necessary to mention that the high driving voltage or driving current to maintain the brightness of the light-emitting element is just the opposite. Fig. 4 is a block diagram showing an embodiment of a display system of a light-emitting diode according to the present invention. The LED unit 43 is composed of an alternating current LED or a high voltage direct current LED, wherein the alternating current LED or the high voltage direct current LED is composed of a plurality of microcrystal grains as shown in the figure. The voltage source 41 is coupled to the LED unit 43 via a variable resistor 42. The photodetector 44 is configured to detect a change in the luminous flux output by the lED unit 43 or a change in the brightness of the LED lighting unit 43. Light detection. . 44 adjusts the resistance value of the variable resistor 42 according to the increased brightness of the LED lighting unit 43, so that the current input to the LED lighting unit 43 is decremented to maintain the LED lighting unit 43 outputting a fixed luminous flux. In this way, the service life of the LED lighting unit 43 can also be extended. In this embodiment, the LED lighting unit 43 may be a single alternating current led or high voltage direct current (LED) or a module composed of a plurality of alternating current coffee or high voltage direct current LEDs, and such as a car light or a traffic light. Fig. 5 is a block diagram showing another embodiment of the display system of the light-emitting diode according to the present invention. The LED unit 53 is formed by an alternating current LED or a high voltage direct current LED, wherein the parent current LED or the high voltage direct current LED is composed of a plurality of microcrystal grains as shown in FIG. The photodetector 54 _ _ _ 兀 the output of the luminous flux, and transmits the detected result to the controller 1378250 51. The control benefit 51 controls the current source 52 to reduce the drive current input to the LED lighting unit 53 in accordance with the increased brightness of the LED lighting unit 53. In the present embodiment, if the LED unit 53 is composed of a high voltage DC LED, the driving current for driving the LED unit 53 can be a pulse width modulation signal generated by a pulse width modulation circuit. The brightness of the LED lighting unit 53 can be controlled by adjusting the duty cycle of the pulse width modulation signal. Fig. 6 is a block diagram showing an embodiment of a warning system for a light-emitting diode having a warning device according to the present invention. LED unit 61 is driven by voltage source 62. The LED unit 61 is composed of a plurality of microcrystalline high voltage DC LEDs as shown in Fig. 1. The detecting device 63 is configured to detect the change of the luminous flux or the brightness of the LED unit 61, and transmit the detected result to the voltage source 62 for adjusting the driving voltage of the voltage source 62 to the LED unit 61, so that the LED The luminous flux output by unit 43 is maintained constant. In another example, the detecting means 63 transmits the detected result to the alerting means 64, and the alerting means 64 determines the number of micro-grain failures in the unit 61 based on the detected result. If the number of failed micro-grains exceeds the predetermined value, the LED unit 61 can still operate normally, but the warning output signal, such as a flashing light 'warning sound or taste, is reminded to remind the user to replace it. The output voltage of the warning device 64 and the adjustment voltage source 62 can be simultaneously operated. 'Also, the number of micro-grains that fail in the LED unit 61 can be known at the same time, and the output voltage of the voltage source 62 can be adjusted so that the luminous flux of the LED unit 43 is maintained. for sure. In one embodiment, the output voltage of the voltage source 1378250 62 can be adjusted by the warning device 64 after recording the number of failed micro-crystals in the LED unit 61. In another embodiment, the detecting device 63 detects the change of the luminous flux output by the LED unit 61 or the brightness change of the LED lighting unit 61, and converts the detected result into the failure of the micro-crystals in the LED lighting unit 61. number. If the number of failures of the micro-grains in the LED lighting unit 61 is greater than a predetermined value, or the percentage of the number of failed micro-grains to the total number of micro-grains is greater than a predetermined percentage, the detecting device 63 outputs a control signal to cause the warning device 64 Output warning signals, such as flashing lights, warning sounds or taste, to remind the user to replace. In another embodiment, the voltage source 62 is a constant voltage source, so the output voltage does not need to be adjusted based on the detection result of the detecting means 63. The detecting device 63 may be a voltage change detecting circuit, a current change detecting circuit or a power change detecting circuit 'transmitting the detected result to the warning device 6z. If the number of failures of the micro-grains in the light-emitting unit 61 is greater than a predetermined value When the percentage of the failed micro-grains to the total number of micro-grains is greater than a predetermined percentage, the alert device 64 outputs an alert signal, such as a flashing light, a warning tone or a smear, to remind the user to replace. Fig. 7 is a block diagram showing another embodiment of the warning system of the light-emitting diode having the warning device according to the present invention. The LED unit 71 is driven by a voltage source 72. The LED unit 71 may be composed of an alternating current LED or a high voltage direct current LED. The alternating current LED or the high voltage direct current LED is composed of a plurality of microcrystal grains as shown in Fig. 1. In the embodiment, the detecting device is a power change detecting device 73 for determining the power variation of the LED unit 71. In the present embodiment, the LED unit 71 is a high voltage DC LED, and the characteristic is illustrated by the characteristic curve shown in FIG. 3 of FIG. 3378, and the voltage source 72 is . When the number of failures of the micro-grains is 4, the power is increased by 62%, because the unit 71 is driven by a constant voltage system, so that the current is increased by 62%. The warning device 74 includes a current limiting resistor 75 and display. Unit %: In this embodiment, the power change detecting device 73 may be a resistor, and the display unit _76 is an LED having a starting voltage of 1.8V, and the power change detecting device=the warning device 74 is connected in parallel. It is assumed that the current flowing through the LED unit 71 is 1 mA in the absence of micro-grain burnout, and the resistance of the power change detecting device is 12 Ω, so that the power change detecting means 73 generates a voltage drop of 1.2 Ω. V is insufficient to cause the display unit 76 to emit light. When the number of failures of the microcrystal grains is ^, the current through the LED unit 71 is 162 mA, and at this time, the voltage drop generated by the power detecting device 73 is 192 V, so that the display unit can emit light. In this manner, the number of failed micro-crystals in the LED unit 71 can be known by the warning device 74. In addition, a plurality of singly or in series can be connected in parallel or in series, and the circuit design can make the number of different failed micro-crystals to be displayed by different display devices for better warning function. Figure 8 is a block diagram of another embodiment of a warning system for a light-emitting diode having a warning device in accordance with the present invention. The LED unit 81 is driven by a first voltage source 82. The LED unit 81 may be composed of an alternating current LED or a high voltage direct current LED. The alternating current LED or the high voltage direct current LED is composed of a plurality of microcrystal grains as shown in Fig. 1. In the present embodiment, the detecting means is a force rate detecting means 83, and the power change detecting means 83 comprises a resistor R1' optocoupler 85 and a current limiting resistor R2. The optical coupler 85 includes an LED 85a and a light-receiving element 85b, wherein the 1378250 is turned on when the light-receiving element 85b receives the light. The resistor R1 has a first end and a second end, wherein the first end is coupled to the LED unit 81, and the second end is coupled to the first voltage source 82. The current limiting resistor R2 has a first end and a second end, wherein the first end is coupled to the first end of the resistor R1. The optical coupler 84 has a first end coupled to the second end of the current limiting resistor R2, and a second end coupled to the second end of the resistor R1. The optical coupler is coupled to the alerting device 84. When the optocoupler 84 is enabled, the alerting LEDs 87 in the alerting device 84 are stopped from emitting light. The warning device 84 includes a second voltage source, resistors R3 and R4, and a warning LED 87. The resistor R3 has a first end coupled to the second voltage source 86. The warning LED assembly 87 has a first end coupled to a second end of the resistor R3 and a second end grounded through the resistor R4, wherein the second end of the warning LED 87 is coupled to the second end The first end of the light receiving element 85b. The voltage of Vc is adjusted by adjusting the resistance values of R3 and R4 so that the warning light-emitting diode 87 can emit light. In the present embodiment, the LED 85a in the optical coupler 85 requires 1.1 V to emit light. It is assumed that in the absence of micro-grain burn-out, the current flowing through the LED unit 81 ® is 100 mA, and the resistance value of R1 is 7.5 Ω, so that the voltage drop generated by R1 is 0.75 V, which is insufficient for the LED 85a to emit light. When the number of failures of the microcrystal grains is 4, the current flowing through the LED unit 81 is 162 mA, and at this time, the voltage drop generated by R1 is 1.21 V, and the LED 85a is caused to emit light, and the light receiving element 85b is turned on. When the light receiving element 85b is turned on, the voltage Vc is pulled to the ground potential, so that the warning light emitting diode 87 cannot emit light, and the warning function is reached. In addition, a monitoring device (not shown) can be used to monitor the voltage Vc at any time. When the voltage Vc becomes 0, it means that the loss of the micro-grain in the LED unit 81 at this time is -ir> Ϊ3 1378250 4. Fig. 9 is a block diagram showing another embodiment of the warning system of the light-emitting diode having the warning device according to the present invention. Compared with the eighth picture, the difference is in the position of the warning light-emitting diode 87, and the warning light-emitting diode 87 is not turned on, and the voltage Vc is pulled to the ground potential when the light-receiving element 85b is turned on. The warning LED 201 will be illuminated. The LED unit 81 is driven by a first voltage source 82. The power change detecting means 83 includes a resistor R1, a photocoupler 85, and a current limiting resistor R2. The optical coupler 85 includes an LEDs 85a and a light receiving element 85b, which are turned on when the light receiving element 85b receives the light. The resistor R1 has a first end and a second end, wherein the first end is coupled to the LED unit 81, and the second end is coupled to the first voltage source 82. The current limiting resistor R2 has a first end and a second end, wherein the first end is coupled to the first end of the resistor R1. The optical coupler 84 has a first end coupled to the second end of the current limiting resistor R2, and a second end coupled to the second end of the resistor R1. The optocoupler is coupled to the alerting device 84. When the optocoupler 84 is enabled, the alerting LEDs 87 in the alerting device 84 are turned on. The warning device 84 includes a second voltage source 86, resistors R3 and R4, and a warning LED 87. By adjusting the resistance values of R3 and R4 to adjust the voltage of Vc, the warning light-emitting diode 87 starts to emit light. In the present embodiment, the LED 85a in the optical coupler 85 requires 1.1 V • to emit light. It is assumed that in the absence of micro-grain burn-in, the current flowing through the LED unit 81 is 10 mA mA. The resistance value of R1 is 7.5 Ώ ′ so that the voltage drop generated by R1 is 0.75 V, which is insufficient for the LED 85a to emit light. When the number of failures of the microcrystal grains y ·«· *···* is 14 1378250 is 4, the current flowing through the LED unit 81 is 162 mA, and the voltage drop generated by ri is 1.21 V, so that the LED 85a can be made to emit light. And the light receiving element 85b is turned on. When the light-receiving element 85b is turned on, the voltage Vc is pulled to the ground potential, so that the warning light-emitting diode 87 is thus illuminated, and the warning function is reached. In addition, it is possible to monitor the voltage yc at any time by using a monitoring device (not shown), and when the voltage Vc becomes 〇, it means that the number of failures of the microcrystal grains in the LED unit 81 at this time is 4. Figure 10 is a block diagram of another embodiment of a warning system for a light-emitting diode having a warning device in accordance with the present invention. The LED unit 1 is driven by a voltage source 102. The LED unit 101 can be composed of an alternating current LED or a high voltage direct current LED, wherein the alternating current LED or the high voltage direct current LED is composed of a plurality of microcrystals as shown in the figure, and the LED unit 1 〇1 consumes a measuring device. In this embodiment, the detecting device can be a power change detecting device, such as the resistor R1 in the figure. In addition, the detecting device may further include an amplifying circuit 1 〇 3 for amplifying the voltage vi and transmitting the result to the controller 104. In this embodiment, an analog to digital converter can be coupled before or after the amplifying circuit to convert the voltage... into a digital signal. The controller 104 can calculate the number of failures of the LED microcrystals in the LED unit 1〇1 by the characteristic curve of the LEDs in the LED unit 101 by the change of the voltage vi, as shown in Fig. 3. The controller 1〇4 then displays the result through the display device 1〇5. The controller 1〇4 can display the number of failures of the LED micro-die in the LED unit 101 through the display device 105 in a text or graphic manner. The figure is a block diagram of another embodiment of an alert system for a light-emitting diode 1378250 having a warning device in accordance with the present invention. LED unit 111 is voltage

Source 112 is driven. The LED unit 111 may be composed of an alternating current LED or a high voltage direct current LED, wherein the alternating current LED or the high voltage direct current LED is composed of a plurality of microcrystal grains as shown in the figure. The LED unit 1U is coupled to a detecting device. In this embodiment, the detecting device can be a power change detecting device, such as the resistor R1 in the figure. In addition, the detecting device may further include a controller and an encoder 114. The controller 113 monitors the change of the voltage V1 and calculates the current LED through the characteristic curve of the LED in the LED unit 111, as shown in FIG. The number of failures of the LED micro-grain of the unit 111. Control 113 then transmits the result to encoder 114 for encoding and then to alarm device 117. The transmission between the encoder 114 and the alerting device 117 can be transmitted via lines, wired or wireless networks, Bluetooth, infrared materials, etc.; It is also necessary that the corresponding transmissions ^ & (10) - 彳) and receiver (receiver) are also necessary. In this embodiment, the warning device! The mouth is the remote poem ' Μ monitors the LED unit (1). This can be applied to the monitoring of traffic signs. The decoding pirate 115 receives the encoder 114 & data and decodes it, and then decodes it (4) to the monitoring unit 116. The monitoring unit 116 can know the number of failures of the LED micro-die in the LED unit 此时lu at this time. In another embodiment, the alerting device 117 can be a remote server that can determine the data transmitted by the encoder 114 via a line, a wireless network, a Bluetooth, or an infrared material. A light-emitting diode with a warning device invented by the warning system § ..... block diagram of the embodiment. In this embodiment, the light is emitted

16 E 1378250 The diode 125 can be composed of an alternating current LED or a high voltage direct current LED, wherein the alternating current LED or the high voltage direct current LED is composed of a plurality of microcrystals as shown in FIG. The light emitting diode 125 can be completed by flip chip or epitaxy. • The detecting device can be a power change detecting device, such as the resistor R1 in the figure, and the photodiode 125 and the resistor R1 can be packaged in the same LED unit 121·. The alerting device 123 includes a current limiting resistor R2 and a display unit. In the figure, the display unit is an LED 124. The operation of the light-emitting diode unit 121, the warning device 123, and the voltage source 122 is the same as that of the light-emitting diode of the seventh embodiment, and will not be described here. The light-emitting diode 125 has a first electrode and a second electrode, wherein the second electrode is coupled to one end of the resistor R1, and one end of the resistor R1 forms a third electrode. Therefore, the light-emitting diode unit 121 has three electrodes, and the voltage source is connected to the first electrode and the second electrode to cause the light-emitting diode 125 to emit light. By measuring the voltage change of the second electrode and the third electrode and then transmitting the characteristic curve as shown in Fig. 3, it can be known that the microcrystal grains in the light-emitting diode 125 are ineffective at this time. Figure 13 is a block diagram showing another embodiment of a warning system for a light-emitting diode having a warning device in accordance with the present invention. The LED unit 131 may be composed of an alternating current LED or a high voltage direct current LED. The alternating current LED or the high voltage direct current LED is composed of a plurality of microcrystal grains as shown in Fig. 1. The warning device 134 includes a current limiting resistor 135 and a display unit 136. In the present embodiment, the display unit 136 is an LED having a starting voltage of 1_8V. The detecting means is an inductance 'inductance 133 produces a voltage drop according to a change in current I. If the voltage drop generated by the inductance 133 is greater than the startup voltage of the display unit 136, the display unit 136 will emit light. In this embodiment, the inductor is used as the power change detection device. The 1378250 device is used for the characteristics that the current change may occur if the micro-LED fails in the AC LED, and the inductor 133 may also be formed by an induction coil. Figure 14 is a block diagram of another embodiment of a warning system for a light-emitting diode having a warning device in accordance with the present invention. The LED unit 141 is driven by a voltage source 142. The LED unit 141 may be composed of an alternating current LED or a high voltage direct current LED, wherein the alternating current LED or the high voltage direct current LED is composed of a plurality of microcrystal grains as shown in FIG. The detecting device is a voltage detecting device 143 formed by connecting resistors R1 and R2 in series. The warning device 144 has a first light emitting diode 145 and a second light emitting diode 146. The first light emitting diode 145 is coupled to the end points N1 and N3, and the second light emitting diode 146 is coupled to the end point N2. N3. When the voltage difference between the terminals N1 and N3 is greater than the starting voltage of the first light-emitting diode 145, the first light-emitting diode 145 emits light. When the voltage difference between the terminals N2 and N3 is greater than the starting voltage of the second LED 146, the second LED 146 emits light. In this way, different light-emitting diodes can be illuminated depending on the number of failures of different micro-grains. If the first light-emitting diode 145 and the second light-emitting diode 146 are simultaneously activated, the first light-emitting diode 145 emits light earlier than the second light-emitting diode 146. In another embodiment, the first light emitting diode 145 and the second light emitting diode 146 have different colors and wavelengths. The present invention has been described above with reference to the specific embodiments, and is merely illustrative of the technical scope of the present invention, and is not intended to limit the scope of the present invention to the embodiments. In the spirit and scope of the invention, the scope of the invention is defined by the scope of the appended claims. V JP·· .,旮 18 1378250 [Simple description of the diagram] Figure 1 is a schematic diagram of the structure of the LED micro-grain. Figures 2A to 2F are LEDs that fail in an AC LED. ^ VIW ^ t ffl 0 B. Number of particles and AC failure. Special tr tr Tr diagram constant voltage system driven by 'AC coffee micro-grain example:::: The display of the first diode according to the present invention is a block diagram of an embodiment of the light emitting diode according to the present invention. "Another sixth figure of 'w' is a warning according to the present invention. A block diagram of an embodiment of a device alert system. The first embodiment of the present invention is a block diagram of another embodiment of a light-emitting diode with a warning device according to the present invention. A block diagram of another embodiment of a light-emitting system with a warning device in accordance with the present invention. The t-picture of the body is a block diagram of another embodiment having a warning device s system according to the present invention. The figure of the body is a block diagram of another embodiment of the illuminating s7F system with warning U according to the invention. The invitation picture of the body is a touch block diagram of the illuminating sensor with the warning device according to the present invention. The figure of the yang body is a block diagram of another embodiment of the illuminating system of the illuminating diode with the warning device according to the present invention. Pole body 19 <S) 1378250 Fig. 13 is a block diagram showing another embodiment of the warning system of the light-emitting diode with the warning device according to the present invention. Fig. 14 is a block diagram showing another embodiment of the warning system of the light-emitting diode having the warning device according to the present invention. [Main component symbol description] 21~voltage 22~current 23~power 31~single PN junction LED failure curve 32~power 33~ luminous flux 34~conversion rate 41~voltage source 42~variable resistance 43~LED unit 44~light Detector 51 to controller 5 2 to current source 53 to LED unit 54 to photodetector 61 to LED unit 62 to voltage source 63 to detecting device 64 to warning device 20 1378250 71 to LED unit 72 to voltage source 73 - power change detecting means 74 - warning means 75 - current limiting resistor 76 - display unit 81 - LED unit 82 - first voltage source 83 - power change detecting means 84 - warning means 85 - light combiner 86 - second Voltage source 101 to LED unit 102 to voltage source 103 to amplifier circuit 104 to controller 105 to display device 111 to LED unit 112 to voltage source 113 to controller 114 to encoder 115 to decoder 116 monitoring unit 117 to warning device 21 1378250 121 to LED unit 122 to voltage source 123 to warning device 131 to LED unit 132 to voltage source 133 to inductor 134 to warning device 135 to current limiting resistor 136 to display unit 141 to LED unit 142 to voltage source 143 to power change Detection device 144~ warning device 22

Claims (1)

1378250 X. Patent application scope: i.—A warning system for a light-emitting diode, comprising: a light-emitting unit composed of a plurality of light-emitting diode micro-crystals; s a detecting device for detecting the light-emitting unit The voltage current, the luminous flux, or the power changes, and outputs a detection result; and a warning device outputs a warning signal according to the detection result to display a damage state of the light-emitting diode micro-crystals in the light-emitting unit. 2. If the warning system of the light-emitting diode described in claim 1 is used, the first 5 ray detecting device is a resistor for generating a voltage drop, and when the pressure drop is greater than the value, Qing Shi Shizhao ^ ^ — 3. As claimed in claim 1, the warning system of the light-emitting diode is wherein the detecting device is an inductor, and a voltage drop is generated according to the current flowing through the light-emitting unit. When the pressure drop is greater than a predetermined value, the warning device is driven. 4. The warning system of the light-emitting diode according to claim 3, wherein the inductor comprises an induction coil. 5. The warning system of the light-emitting diode according to claim 1, wherein the detecting device comprises at least one resistor, capacitor or inductor for detecting a voltage, current or power change of the K-Xuanguang light body. . 6. The warning system of the light-emitting diode according to the fifth aspect of the patent application, the charging detection device further comprises an amplifying circuit, and the detected detection result is amplified and transmitted to the warning device. 7. The warning system of the light-emitting diode according to claim 5, wherein the device further comprises an encoding circuit, and the detection result detected by the intrusion device is encoded and transmitted to the warning device. 8' is the display system of the light-emitting diode according to item 1 of the patent application scope, wherein the warning I includes the data of the decoding device. The display system of the light-emitting diode according to claim 1, wherein the warning device comprises a display device, a light-emitting diode, a sound generating device or a computer. ^1〇. The warning system of the light-emitting diode according to claim 1, wherein the warning device is a remote server, through a line, a line, a 'wire, a wireless network, a Bluetooth or Infrared is communicated with the detection device. The warning system of the light-emitting diode according to claim 1, wherein the warning device comprises a first display device and a second display device, wherein the light-emitting diode in the light-emitting unit is micro- When the number of grain damage reaches a first predetermined value, the first display device is driven; when the amount of micro-grain damage of the light-emitting element in the light-emitting unit reaches a second value, the first display is driven. Set. ^ I2. The warning of the light-emitting diode according to claim 1, wherein the first display device is a first light-emitting diode, and the second device is a second light-emitting diode. . The first light-emitting diode and the second light-emitting diode of the light-emitting diode according to Item 12 of the patent scope of the invention are the same wavelength. / 14· The warning system of the light-emitting diode according to item 1 of the scope of application, the first four of the light-emitting units include a light-emitting diode, the light-emitting diode ^/8250 wi July//day The replacement replacement page is an AC light-emitting diode or a high-voltage DC light-emitting diode. 15. The warning system for a light-emitting diode according to claim 1, wherein the light-emitting unit is composed of a plurality of alternating current light-emitting diodes or high-voltage direct current light-emitting diodes having a light-emitting diode micro-grain structure. composition. The warning system of the light-emitting diode according to claim 1, wherein the light-emitting diode and the detecting device are packaged in the same unit structure. The warning system of the light-emitting diode according to claim 16, wherein the light-emitting diode is further coupled to a resistor, the light-emitting diode has a first end and a second end, The resistor has a first end and a second end. The first end of the LED forms a first electrode, and the second end of the LED forms a second electrode with the first end of the resistor. The first end forms a third electrode. 18. The warning system of the light-emitting diode according to the scope of claim 2, wherein the controller further comprises a controller, and according to the detection result, φ the light-emitting diode micro-crystal in the light-emitting unit is obtained. The amount of damage. The warning system of the light-emitting diode according to claim 18, wherein the controller adjusts a driving current or a driving voltage input to the light-emitting diode according to the detection result. 20. The warning system of the light-emitting diode according to claim 18, further comprising: a current source, outputting a driving current to the light-emitting diode, and controlling the driving current by the 泫 controller the size of. 21. The warning <5" 1378250 system of a light-emitting diode according to claim 19, wherein the current source comprises a current mirror circuit. 22. The warning system of the light-emitting diode according to claim 19, wherein the driving current is a pulse width modulation signal, and the current source is a pulse width modulation circuit, and the pulse width modulation circuit The path is controlled by the controller to adjust the duty cycle of the pulse width modulation signal. 23. The warning system for the LEDs as described in item a of the 5th patent scope of the application includes: A voltage source outputs a driving voltage to the light emitting diode and is controlled by the controller to adjust the driving voltage. 4. The warning system of the light-emitting diode according to claim 18, wherein the detecting device is a light detecting unit for detecting the brightness of the light-emitting diode and detecting The result is transferred to the controller. ^ 25. When the brightness of the warning system of the light-emitting diode described in claim 18 and the brightness of the Xiantian 5-inch light-emitting diode are increased, the controller reduces a driving current of the input s-light emitting body . The display system of the light-emitting diode according to the invention of claim 2, wherein the detecting device is a power change detecting device, comprising: a light surface coupled to the warning device, when flowing through the light emitting unit The current increases by a pre-depreciation of 4, and when the optocoupler is enabled, the chisel-warning LED is turned on or off. . The device of claim 26, wherein the optical coupler comprises: D: a light emitting element; and a light emitting element coupled to the warning device when flowing When the amount of current of the correction page is increased by the light-emitting unit 1378250, qf, and the predetermined amount of light is turned on, the light-emitting element is turned on to emit light, so that the light-receiving element is turned on.