JP2006344913A - Full-color light emitting diode - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a full-color LED without increasing the cost and the size of a device itself when extending the scope of a color that can be reproduced by using multiple primary colors larger than three primary colors in the number of colors. <P>SOLUTION: A plurality of kinds of primary colors in accordance with a plurality of peak current values are emitted by allowing a pulse current (cycle T between groups of pulses is 25 ms or less including pulses of different peak current values) having a plurality of peak current values to flow in a variable wavelength green LED 22, by using the variable wavelength green LED 22 where an emitting wavelength varies by a change of a current value connected to a single red LED 20 and a pulse power supply 16 and a single blue LED 24. The emitting intensity of primary colors such as G and Gx is adjusted by controlling a duty ratio. The full-color LED of the multiple primary colors can be obtained by mixing a primary color, Fr or the like by the red LED 20 and a primary color, Fb or the like by the blue LED 24 where emitting intensity is adjusted with the primary colors, G, Gx or the like where emitting intensity is adjusted as in a normal case. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a full-color light emitting diode that uses more than three primary colors.

  Conventional full-color light emitting diodes (LEDs) usually include three semiconductor chips (monochromatic LEDs) that emit light of three primary colors of red, green and blue in one package. By adjusting the forward current flowing through each single color LED to adjust the light emission intensity of each single color LED and mixing the colors, light emission of various hues is obtained as a whole.

  FIG. 6 is a chromaticity diagram showing the range of colors reproduced by a conventional full color LED. More specifically, FIG. 6 shows a CIE (Commission Internationale de l'Eclairage: CIE) in which various colors are represented as three-dimensional coordinates by the blending ratio of red, green, and blue light and projected onto the xy plane. It is an xy chromaticity diagram by the International Lighting Commission). The area in the curve A on the xy chromaticity diagram (the area indicated by each predetermined range of chromaticity coordinates x and y) represents all the colors. For example, the upper left area is green and the lower left area is blue. The right side area represents red, the upper right area (x = 0.45 to 0.5, y = 0.45 to 0.5) represents yellow, and the center area represents white. Although not shown in FIG. 6, when two colors indicated by chromaticity coordinates (x1, y1) and (x2, y2) on the xy chromaticity diagram are mixed, the resulting color is the two colors. It is on a straight line. Although omitted in FIG. 6, normally, the wavelength of each color is given in nm units around the curve A on the xy chromaticity diagram.

  In FIG. 6, white circles indicate three primary colors by 3in1 fullcolor LED (manufactured by Nichia Corporation), Fr is red (chromaticity coordinates x = 0.700, y = 0.300), and Fg is green (color) Degree coordinates x = 0.170, y = 0.700), and Fb is blue (chromaticity coordinates x = 0.130, y = 0.075). The LEDs obtain light emission of various hues as a whole by adjusting the light emission intensity of each single color LED that emits the three primary colors Fr and the like and mixing the colors. For example, in the case of a 3in1 fullcolor LED, light emission of various hues within a triangular range indicated by the three primary colors Fr-Fg-Fb is obtained. 3in1 fullcolor LED is a generic name for NSTM type full color LED, NECM type full color LED, NSCM type full color LED, NSSM type full color LED (all manufactured by Nichia Corporation).

  As described above, the color range that can be reproduced by each LED is within the triangular range determined by the three primary colors. For this reason, there is a problem that not all the colors in the curve A in FIG. 6 can be reproduced. Therefore, attempts have been made to expand the range of colors that can be reproduced by using more than three primary colors. For example, Patent Document 1 describes that, for the purpose of performing spectral color reproduction by multi-primary color display, LED elements of n colors (n> 3) emit light and color light is mixed to reproduce a target color. Has been. Patent Document 2 describes the use of m types of light sources having different spectral distributions for the purpose of realizing a multi-primary color display system. For example, it is supposed that six types of LED array light sources having different emission wavelength distributions can have emission peaks of up to six primary colors. Patent Document 3 describes a display device capable of displaying with a larger number of primary colors than the number of sub-pixels constituting one pixel. Specifically, it is described that a plurality of light sources having different emission colors are provided, and the display period is time-divided to control the emission color of the light source in each period to be different. Patent Document 4 describes a multi-primary color display device, which includes a multi-primary light source configured to emit four or more primary colors and various color separation means.

JP 2003-143417 A JP 2003-107472 A JP 2004-138827 A JP 2004-286964 A

  As described above, Patent Document 1 requires n-color (n> 3) LED elements, Patent Document 2 requires m types of light sources, and Patent Document 3 requires a plurality of light sources having different emission colors. In Patent Document 4, a multi-primary color light source configured to emit four or more primary color lights is required. For this reason, in order to widen the range of colors that can be reproduced, a large number of light sources with different emission colors, a large number of types of light sources, a plurality of light sources with different emission colors, and a large number of primary color lights can be emitted. A multi-primary light source is required. For this reason, there is a problem that not only the cost increases but also the size of the apparatus itself increases.

  Accordingly, an object of the present invention has been made to solve the above-described problem, and in expanding the range of colors that can be reproduced by using more than three primary colors, the cost of the apparatus itself is not increased. The object is to provide a full color LED which does not increase in size.

  The full color light emitting diode of the present invention is a full color light emitting diode comprising a red light emitting diode, a blue light emitting diode, and a green wavelength tunable light emitting diode whose emission wavelength changes according to a change in current value. A pulse current having a predetermined number of peak current values flowing through the light emitting diode and having a period between pulse groups including pulses having different peak current values being equal to or less than a predetermined pulse period is supplied.

  Here, in the full color light emitting diode of the present invention, the blue light emitting diode is a blue wavelength variable light emitting diode whose light emission wavelength is changed by a change in current value, and a predetermined number of peak current values are set in the blue wavelength variable light emitting diode. It is possible to pass a pulse current having a pulse current having a period between pulse groups including pulses having different peak current values that is equal to or less than a predetermined pulse period.

Here, in the full color light emitting diode of the present invention, the red light emitting diode is a red wavelength variable light emitting diode whose light emission wavelength is changed by a change in current value, and a predetermined number of peak current values are applied to the red wavelength variable light emitting diode. It is possible to pass a pulse current having a pulse current having a period between pulse groups including pulses having different peak current values that is equal to or less than a predetermined pulse period.
Here, in the full color light emitting diode of the present invention, the predetermined pulse period can be set to 25 ms.
The full color light emitting diode of the present invention is a full color light emitting diode comprising a red light emitting diode, a blue wavelength tunable light emitting diode whose emission wavelength is changed by a change in current value, and a green light emitting diode, wherein the blue wavelength variable A pulse current having a predetermined number of peak current values flowing through the light emitting diode and having a period between pulse groups including pulses having different peak current values being equal to or less than a predetermined pulse period is supplied. In the full color light emitting diode, in addition to the blue wavelength tunable light emitting diode, the red light emitting diode is a red wavelength tunable light emitting diode whose light emission wavelength is changed by a change in current value. It is possible to flow a pulse current having a number of peak current values of which the period between pulse groups including pulses having different peak current values is equal to or less than a predetermined pulse period.
The full color light emitting diode of the present invention is a full color light emitting diode comprising a red wavelength tunable red light emitting diode whose light emission wavelength changes according to a change in current value, a blue light emitting diode, and a green light emitting diode, wherein the red wavelength A pulse current having a predetermined number of peak current values through the variable light emitting diode and having a period between pulse groups including pulses having different peak current values being equal to or less than a predetermined pulse period is supplied. In the full color light emitting diode, in addition to the red wavelength tunable light emitting diode, the green light emitting diode is also a green wavelength tunable light emitting diode whose emission wavelength changes according to a change in current value. It is possible to flow a pulse current having a number of peak current values of which the period between pulse groups including pulses having different peak current values is equal to or less than a predetermined pulse period.

  According to the full color light emitting diode of the present invention, a red LED connected to a DC power source, a wavelength variable green LED whose emission wavelength changes due to a change in current value connected to a pulse power source, and a blue LED connected to a DC power source And a pulse current having a plurality (predetermined number) of peak current values in the wavelength tunable green LED, and a period between pulse groups including pulses having different peak current values is equal to or less than a predetermined pulse period (25 ms). By supplying a certain pulse current, it is possible to emit a plurality of types of primary colors corresponding to a plurality of peak current values. The emission intensity of the primary color in the wavelength tunable green LED can be adjusted by controlling the duty ratio. A multi-primary full-color LED can be realized by mixing primary colors G and Gx whose emission intensity is adjusted in this way. Since the total number of LEDs remains three as in the case of the three primary colors, there is no increase in cost and the size of the apparatus itself when expanding the range of colors that can be reproduced by using more than three primary colors. There is an effect that a full-color LED that does not increase can be provided.

  Hereinafter, each embodiment will be described in detail with reference to the drawings.

  First, the principle of the full color LED of the present invention will be described, and then the specific configuration of the full color LED will be described. FIG. 1 is a chromaticity diagram showing the principle of a full-color LED in Example 1 of the present invention. FIG. 1 is a chromaticity diagram similar to FIG. 6, and the same symbols as those in FIG. In FIG. 1, white square marks indicate primary colors of an example of a wavelength-tunable green LED (InGaN SQW green LED: manufactured by Nichia Corporation) used in the present invention, and G is green (chromaticity coordinate x = 0.205, y = 0.723), Gx is green (chromaticity coordinates x = 0.121, y = 0.638), and Gy is blue-green (chromaticity coordinates x = 0.105, y = 0.362). The wavelength tunable LED has a characteristic that the emission wavelength changes according to the change of the current value, and the wavelength tunable green LED emits the color on the dotted line (curve) Ag shown in FIG. 1 by the change of the current value. Can do. Accordingly, the primary colors Fr, G, Gx, and Fb are primary colors Fr, G, Gx, and Fb by replacing the primary color Fg of the 3in1 fullcolor LED by the primary green LED with the two primary colors G and Gx of the wavelength-tunable green LED and adjusting the emission intensity as appropriate. A full color LED can be realized. The primary color Gx can be an arbitrary point on the curve Ag. When the four primary colors Fr, G, Gx, and Fb are fixed, the range that can be reproduced by the four primary color full-color LEDs is a rectangle surrounded by the four primary colors Fr, G, Gx, and Fb on the chromaticity diagram of FIG. It becomes the range.

3in1
By replacing the primary color Fg of the full-color LED, which is a single-color green LED, with the wavelength-tunable green LED and adjusting the emission intensity as appropriate and mixing the colors, the primary colors Fr, G, Gx, Gy, and Fb can be realized. . The primary color Gy can be arbitrarily set to a point on the curve Ag. When the five primary colors Fr, G, Gx, Gy, and Fb are fixed, the range that can be reproduced by the five primary colors full color LED is based on the five primary colors Fr, G, Gx, Gy, and Fb on the chromaticity diagram of FIG. It is the range of the enclosed rectangle. As described above, by setting an arbitrary number n (> 0) of primary colors including the primary color G on the dotted line Ag, an (n + 2) primary color full-color LED can be realized.

  Next, a specific configuration of the full color LED will be described. FIG. 2 is a block diagram showing the configuration of the full color LED 10 according to the first embodiment of the present invention. In FIG. 2, reference numeral 12a is an input end, 14 is a DC power source connected to the input end 12a, 20 is a red LED (single color LED) connected to the DC power source 14, 26a is an output end of the red LED 20, and 12b is an input end. , 16 is a pulse power source connected to the input terminal 12b, 22 is a wavelength variable green LED whose emission wavelength is changed by a change in current value connected to the pulse power supply 16, 26b is an output terminal of the wavelength variable green LED 22, and 12c is an input Reference numeral 18 denotes a DC power source connected to the input terminal 12 c, 24 denotes a blue LED (single color LED) connected to the DC power source 18, and 26 c denotes an output terminal of the blue LED 24. The full color LED 10 preferably has a configuration in which the red LED 20, the wavelength variable green LED 22 and the blue LED 24 are built in one package. As the wavelength variable green LED 22, NSPG type green LED or NSPE type blue green LED manufactured by Nichia Corporation is suitable.

  As shown in FIG. 2, a pulse current having a predetermined number of peak current values is supplied from the pulse power supply 16 to the wavelength variable green LED 22 at a predetermined pulse frequency. As described above, the wavelength of the tunable light emitting diode 22 changes its emission wavelength by changing the value of the flowing current. Therefore, by supplying a pulse current having a plurality of (predetermined number) peak current values to the wavelength tunable green LED 22, a plurality of types of colors corresponding to the plurality of peak current values (for example, G, Gx, Gy in FIG. 1). Can be emitted.

  FIG. 3 is a pulse waveform diagram for explaining a method of controlling the emission color of the wavelength variable green LED 22. In FIG. 3, the horizontal axis represents time (μs), and the vertical axis represents the current (mA) flowing through the wavelength tunable green LED 22. T0, t1,. . . Are equally spaced. As shown in FIG. 3, the predetermined number of peak current values is, for example, two (two steps), ie, Ix (mA) corresponding to the primary color Gx and Ig (mA) corresponding to the primary color G in FIG. . Tx is the pulse width of the pulse X having a peak current value of Ix (mA), and Tg is the pulse width of the pulse G having a peak current value of Ig (mA). T is a pulse group S1 including two pulses X and G (pulses having different peak current values) having different peak current values Ix (mA) and Ig (mA), and another similar pulse group S2. (Period between pulse groups, that is, a predetermined pulse period). Each pulse group S1 and the like includes the same number of pulses as the number of peak current values (predetermined number). Here, when the pulse period T is set to 25 ms or more (or the frequency of the pulse group S1 or the like is 40 Hz or less), light emission appears to blink to human eyes. However, when the pulse period T is set to 25 ms or less (or the frequency of the pulse group S1 or the like is 40 Hz or more), each of the eyes appears to be lit. The boundary frequency at which the blinking light appears to be lit is called critical fusion frequency (CFF). CFF varies depending on light intensity, wavelength, etc., but it is said that the CFF of a normal person under standard stimulation conditions is about 40 Hz (by Keisuke Kobayashi, “Electronic Display”, page 199, March 1992). First edition published on the 10th, published by the Institute of Electronics, Information and Communication Engineers). Therefore, the pulse period T needs to be 25 ms or less (or the frequency of the pulse group S1 or the like is 40 Hz or more). In FIG. 3, only two pulse groups (S1 and S2) are shown for convenience, but if the pulse period T is 25 ms or less, three or more pulse groups can be used.

  The light emission intensities of the primary colors G and Gx include a method of changing the pulse widths Tx and Tg and a method of changing the number of pulses included in a unit time. The above two methods are the same in the sense that the duty ratio (Tx / T or Tg / T, indicating how long the color emits during the pulse period T) is controlled. is there. By mixing the primary colors G and Gx whose emission intensity is adjusted in this way, a full-color LED of four primary colors such as primary colors Fr, G, Gx, and Fb can be realized.

  FIG. 4 is another pulse waveform diagram for explaining the emission color control method of the wavelength-tunable green LED 22. In FIG. 4, the same symbols as those in FIG. As shown in FIG. 4, the predetermined number of peak current values is, for example, Ig (mA) corresponding to the primary color G in FIG. 1, Ix (mA) corresponding to the primary color Gx, and Iy (mA) corresponding to the primary color Gy. And three (three stages). Ty is the pulse width of the pulse Y having a peak current value of Iy (mA). Also in the case shown in FIG. 4, the pulse period T needs to be 25 ms or less (or the frequency of the pulse group S3 or the like is 40 Hz or more) as described above. In FIG. 4, only two pulse groups (S3 and S4) are shown for the sake of convenience. However, if the pulse period T is 25 ms or less, three or more pulse groups can be used.

  The emission intensity of the primary color Gy can also be adjusted by controlling the duty ratio (Ty / T). The primary colors G, Gx and Gy whose emission intensity is adjusted in this way, the primary color Fr by the red LED 20 and the primary color Fb by the blue LED 24 whose emission intensity is adjusted by adjusting the forward current as usual, By combining the primary color G pulse train, primary color Gx pulse train, and primary color Gy pulse train as shown in FIG. 4 at an appropriate timing, a primary color full-color LED such as primary colors Fr, G, Gx, Gy, and Fb is realized. can do. In the same manner as described above, by setting an arbitrary number n (> 0) of primary colors with an arbitrary number of peak current values, an (n + 2) primary color full color LED can be realized.

  As described above, according to the first embodiment of the present invention, the red LED 20 connected to the DC power supply 14, the wavelength variable green LED 22 whose emission wavelength changes due to the change of the current value connected to the pulse power supply 16, and the DC power supply 18. The pulse current having a plurality of (predetermined number) peak current values is allowed to flow through the wavelength variable green LED 22 at a predetermined interval (1/40 Hz or less). A plurality of types of primary colors can be emitted. The emission intensity of the primary colors G, Gx, etc. can be adjusted by controlling the duty ratio. The primary colors G, Gx, etc., whose emission intensity is adjusted in this way, and the primary colors Fr, etc. by the red LED 20 and the blue LED 24, whose emission intensity is adjusted by adjusting the forward current as usual, are primary colors. A multi-primary full color LED can be realized by mixing colors with a pulse train such as G and Gx at an appropriate timing. Even if there are multiple primary colors more than three primary colors, the total number of LEDs remains three as in the case of the three primary colors. For this reason, it is possible to provide a full-color LED that does not increase the cost and does not increase the size of the device itself when expanding the range of colors that can be reproduced by using more than three primary colors.

  FIG. 5 is a chromaticity diagram showing the principle of a full-color LED in Example 2 of the present invention. FIG. 5 is a chromaticity diagram similar to FIG. 1, and the same symbols as those in FIG. In FIG. 5, black triangle marks indicate primary colors of a wavelength-tunable blue LED (preferably InGaN SQW blue LED) used in Example 2, and B is blue (chromaticity coordinates x = 0.151, y = 0.032). ), Bx is blue (chromaticity coordinates x = 0.116, y = 0.104). The wavelength-tunable blue LED can emit the color on the curve B-Bx shown in FIG. 5 by changing the current value. Therefore, the primary colors Fr, Gx are adjusted by appropriately adjusting the emission intensity using the two primary colors B and Bx of the wavelength tunable blue LED, the wavelength tunable green LED 22 of Example 1, and the monochromatic red LED of 3in1 fullcolor LED, and mixing the colors. , Gx, etc. and B, Bx, etc. multi-primary color full color LEDs can be realized. The range that can be reproduced by the multi-primary color full-color LED is a range surrounded by primary colors Fr, G, Gx, etc. and B, Bx, etc. on the chromaticity diagram of FIG.

  As the wavelength tunable blue LED, NSPB type blue LED manufactured by Nichia Corporation is suitable. The power source of the wavelength tunable blue LED is a pulse power source similar to the wavelength variable green LED 22 described in the first embodiment, and the emission color control method of the wavelength variable blue LED is the same as that of the wavelength variable green LED 22 described in the first embodiment. Therefore, explanation is omitted.

  As described above, according to the second embodiment of the present invention, the wavelength-tunable blue LED can be used in place of the monochromatic blue LED of the first embodiment. As a result of using two wavelength tunable LEDs, it is possible to provide a multi-primary full-color LED capable of reproducing a wider range of colors than in the first embodiment.

    In Example 2 described above, a wavelength variable blue LED was used in addition to the wavelength variable green LED of Example 1. Similarly, a wavelength variable red LED can be further added to the second embodiment. The wavelength-tunable red LED can also emit a color on a desired curve (R-Rx, not shown) by changing the current value. Accordingly, the light emission intensity is appropriately determined using the two primary colors R and Rx of the wavelength variable red LED, the two primary colors B and Bx of the wavelength variable blue LED of Example 2, and the two primary colors G and Gx of the wavelength variable green LED 22 of Example 1. By adjusting and mixing the colors, multi-primary full-color LEDs such as primary colors R, Rx, etc., B, Bx, etc. and G, Gx, etc. can be realized. The range that can be reproduced by the multi-primary color full-color LED is a range surrounded by primary colors R, Rx, etc., G, Gx, etc., B, Bx, etc. (not shown) on the chromaticity diagram.

  The power source of the wavelength tunable red LED is a pulse power source similar to the wavelength tunable green LED 22 described in the first embodiment, and the emission color control method of the wavelength tunable red LED is the same as that of the wavelength tunable green LED 22 described in the first embodiment. Therefore, explanation is omitted.

  As described above, according to the third embodiment of the present invention, the variable wavelength red LED can be used instead of the single-color red LED of the first or second embodiment. As a result of using three wavelength tunable LEDs, it is possible to provide a multi-primary full-color LED capable of reproducing a wider range of colors compared to Example 1 or 2.

  In the above-described Examples 1 to 3, the combination of the wavelength tunable LEDs is only green (Example 1), green and blue (Example 2), and green, blue and red (Example 3). However, as a matter of course, the combination of the wavelength tunable LEDs can be arbitrarily combined with only blue, only red, blue and red, green and red, and the like.

  As an application example of the present invention, a multi-primary full color LED can be applied to, for example, a color display.

It is a chromaticity diagram which shows the principle of the full color LED in Example 1 of this invention. It is a block diagram which shows the structure of full color LED10 in Example 1 of this invention. It is a pulse waveform diagram for demonstrating the light emission color control method of wavelength variable LED22. It is another pulse waveform diagram for demonstrating the emitted light color control method of wavelength variable LED22. It is a chromaticity diagram which shows the principle of the full color LED in Example 2 of this invention. It is a chromaticity diagram which shows the range of the color reproduced by the conventional full color LED.

Explanation of symbols

10 full color LED, 12a, 12b, 12c input terminal, 14, 18 DC power supply, 16 pulse power supply, 20 red LED, 22 wavelength variable green LED, 24 blue LED, 26a, 26b, 26c output terminal.

Claims (4)

A full-color light emitting diode comprising a red light emitting diode, a blue light emitting diode, and a green wavelength tunable light emitting diode whose emission wavelength changes according to a change in current value,
A pulse current having a predetermined number of peak current values and a period between pulse groups including pulses having different peak current values being less than or equal to a predetermined pulse period is caused to flow through the green wavelength tunable light emitting diode. Full color light emitting diode characterized by.   2. The full-color light-emitting diode according to claim 1, wherein the blue light-emitting diode is a blue wavelength-variable light-emitting diode whose emission wavelength changes according to a change in current value, and the blue wavelength-variable light-emitting diode has a predetermined number of peak current values. A full-color light-emitting diode, characterized by flowing a pulse current which is a pulse current and whose period between pulse groups including pulses having different peak current values is equal to or less than a predetermined pulse period.   3. The full color light emitting diode according to claim 2, wherein the red light emitting diode is a red wavelength variable light emitting diode whose light emission wavelength is changed by a change in current value, and the red wavelength variable light emitting diode has a predetermined number of peak current values. A full-color light-emitting diode, characterized by flowing a pulse current which is a pulse current and whose period between pulse groups including pulses having different peak current values is equal to or less than a predetermined pulse period. 4. The full color light emitting diode according to claim 1, wherein the predetermined pulse period is 25 ms.

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