JP2017103185A - Illumination including light emitting diode - Google Patents

Abstract

PROBLEM TO BE SOLVED: To change the luminous color of a light emitting diode with a simple circuit constitution.SOLUTION: Illumination including a light emitting diode includes a light emitting diode 1 and a power supply 3 connected to the light emitting diode. The power supply 3 includes a pulse generating circuit 4 generating a pulse voltage having a peak value (Vh) that exceeds the rising voltage (Vs) of the light emitting diode 1 in a forward direction. The pulse generating circuit 4 supplies a pulse voltage to the light emitting diode 1 to cause the light emitting diode 1 to emit light, the pulse voltage having a peak value (Vh) that exceeds a rising voltage (Vs) in a forward direction.SELECTED DRAWING: Figure 2

Description

  The present invention relates to lighting using a light emitting diode as a light source, and in particular, indoor and outdoor lighting fixtures, back lighting of display panels such as liquid crystals, lighting for vehicles such as car headlights and interior lighting, signage and lighting for decoration. The present invention relates to illumination using a light-emitting diode that is optimal for illumination used for a light source of a projector as a light source.

  Light emitting diodes are used as various types of lighting such as back lighting for monitors, indoor and outdoor lighting, and lighting for vehicles, taking advantage of high luminous efficiency and long life characteristics. As shown in FIG. 11, in order to apply a forward voltage (Vs) to the light emitting diode, the light emitting diode illuminates the light emitting diode 91 via a current limiting element such as a current limiting resistor 98 or a constant current circuit. A DC power supply 93 is connected. As shown in FIG. 12, when the voltage-current characteristic of the light emitting diode 91 exceeds the forward rising voltage (Vs), it rapidly increases. Therefore, only the voltage is controlled to stabilize the current value to the predetermined value. Because it is difficult to do. In this illumination, the power consumption of a current limiting element such as a current limiting resistor or a constant current circuit causes a reduction in power efficiency.

In addition, the light emitting diode has a drawback that the emission color specified by the semiconductor element cannot be changed. This is because the wavelength of the emission color is specified by the energy gap of carriers recombined in the PN junction layer. The light-emitting diode is specified by the following formula, where Eg is the energy gap of energy and ν is the frequency of light emission color (reciprocal 1 / λ of wavelength λ).
Eg = hν
However, in this expression, h is a Planck constant.

  In the light emitting diode, since the emission color is specified by the energy gap of the carrier specified by the semiconductor material, the emission color cannot be changed, and only the luminance by the current value is controlled. For example, a white light-emitting diode is realized by combining a blue light-emitting diode and a yellow phosphor, and red, blue, and green white light-emitting diodes are emitted together to emit white light. Lighting is realized. However, blue light-emitting diodes and white light of the three primary colors emit white light by accurately controlling the color balance of the light emission color, so it is extremely difficult to adjust the color balance, and it is extremely difficult to make the light emission color ideal white. This is difficult, and this is a cause of lowering the yield. White light emitting diodes cause a slight variation in phosphor filling amount, causing the emission color to deviate from white, and white illumination that combines three primary color light emitting diodes emits red, blue, and green light. This is because the unbalance of the light emission intensity of the diode shifts the white color point. To make matters worse, the human eye has the ability to clearly discriminate even the slight deviation of white, so the manufacture of white light-emitting diodes that emit white light at specific color points requires extremely high manufacturing processes. Further, since the manufactured white light emitting diodes are selected to manufacture those having a specific color point, there is a disadvantage that the equipment cost becomes high.

  Also, since the light emission color of the light emitting diode cannot be changed, lighting that needs to change the light emission color needs to adjust the light emission intensity of each color light emitting diode by combining multiple light emitting diodes with different light emission colors. Cost increases.

  Furthermore, as described above, since the wavelength of light emitted from the energy gap of the carriers recombined in the PN junction layer is specified, the light emitting diode exhibits light emission characteristics having an emission peak with a very narrow bandwidth. As shown in FIG. 13, the white light-emitting diode is recognized as white by the human eye by mixing the blue light of the band spectrum with an extremely strong light emission peak and the light emitted by the yellow phosphor having a gentle and wide bandwidth. It is adjusted so that. The illumination having the emission characteristics shown in FIG. 13 has various adverse effects because the emission peak of the blue band spectrum is extremely strong. The ideal illumination is to widen the bandwidth of the band spectrum to reduce the intensity difference due to the wavelength, but the light emitting diode has a wavelength of light emitted by the energy gap of carriers recombined by the PN junction layer. There is a disadvantage that the emission peak becomes strong due to the emission characteristics of a narrow band spectrum that is specified.

Special Table 2002-542503 gazette

  The present invention has been developed for the purpose of solving the above-described drawbacks of conventional light-emitting diode illumination. An important object of the present invention is to provide illumination of a light emitting diode capable of changing the emission color with a simple circuit configuration while increasing power efficiency.

Means and effects for solving the problems

  An illumination including a light emitting diode according to the present invention includes a light emitting diode 1 and a power source 3 connected to the light emitting diode 1. The power supply 3 includes a pulse generation circuit 4 that generates a pulse voltage (Vh) having a peak value (Vh) that exceeds the forward rise voltage (Vs) of the light emitting diode 1, and the pulse generation circuit 4 includes the rise voltage (Vs) of the light emitting diode 1. ) To supply a pulse voltage having a peak value (Vh) exceeding 1) to cause the light emitting diode 1 to emit light.

  The above illumination has the feature that light emission can be shifted from the standard emission color of the light emitting diode to the short wavelength side with a simple circuit configuration while improving power efficiency. This is because the above illumination applies a pulse voltage having a peak value (Vh) exceeding the forward voltage (Vs) in the forward direction of the light emitting diode to the light emitting diode to accelerate and recombine the carriers with the high voltage. . The light emission wavelength λ of the light emitting diode is specified by the energy gap of the carriers that recombine in the PN junction layer, but the above illumination applies a pulse voltage higher than the forward rising voltage (Vs). Since light is emitted, the energy of carriers recombined in the PN junction layer can be increased to emit light of a short wavelength side.

  Furthermore, in the above illumination, when the peak value (Vh) is increased and the effective current increases, the pulse width of the pulse voltage can be narrowed to prevent the light emitting diode from being damaged. Light can be emitted by applying a voltage far exceeding (Vs). As a result, the peak value (Vh) of the pulse voltage can be increased and the energy when electrons and holes are recombined can be increased, so that the peak value (Vh) of the pulse voltage is increased in the forward rising voltage (Vs). It is also possible to increase it to several times higher than the standard emission color that emits light by applying a forward rising voltage (Vs).

  As the temperature rises, the luminous efficiency of the light emitting diode decreases. For example, when the temperature rises to 80 ° C., the luminous efficiency decreases by 20%. For this reason, the conventional illumination has a defect that the luminous efficiency decreases when the temperature rises by passing a large current through the light emitting diode. On the other hand, the illumination of the present invention instantaneously supplies a pulse voltage with a high peak value (Vh) to cause the light emitting diode to emit light instantaneously. The light emission efficiency can be increased by reducing the temperature rise while reducing the temperature. More advantageously, the above illumination causes light emitting diodes to emit light instantaneously at a pulse voltage with a high peak value (Vh), and then stops emitting light. In order to achieve a feature that enables bright illumination while minimizing power consumption and reducing temperature rise. This is because the characteristics of the human nerve cell are effectively used to make it blink with a pulse voltage. The nerve cells of the human eye have a refractory period in which, when an action potential is generated once upon receiving a light stimulus, the next stimulus received within a certain period of time decreases in reactivity and does not excite. In particular, the light-emitting diode can be blinked by effectively utilizing an absolute refractory period that does not respond at all to a large stimulus.

  The above illumination causes the light emitting diode to emit light strongly and momentarily with a pulse voltage having a high peak value (Vh), so that the human eye recognizes a momentary strong light stimulus. Thereafter, even if the light emitting diode is turned off during the refractory period when it does not respond to light stimulation, the human eye perceives it as bright illumination. For this reason, the above illumination realizes bright illumination while increasing the ratio of the extinguishing time to the light emitting time of the light emitting diode, that is, while making the effective current extremely small. By the way, in the experiment of the present inventor, a blue light emitting diode made of gallium nitride has a peak value (Vh) of about 4 times the forward rising voltage (Vs), a pulse width (W) of 10 μsec, and a pulse period. When a pulse voltage with a pulse period of 1 msec and a pulse voltage with a pulse period of 0.1 msec are applied to emit light, there is almost no difference in brightness perceived by the eyes. This realizes an epoch-making feature that the power consumption can be reduced to 1/10 and illumination with almost the same brightness can be realized. The pulse voltage with a pulse width (W) of 1 μsec and a pulse period of 1 msec has an extremely small duty of 0.1%, and consumes less power than a light emitting diode emitting direct current with a duty of 100%. The lighting will be dramatically reduced and realized by the eyes.

  Furthermore, the illumination according to the present invention supplies a high peak value (Vh) voltage exceeding the forward rising voltage (Vs) to the light emitting diode without using a current limiting element, thereby making the light emitting diode highly efficient. Can emit light. This is because a pulse voltage is supplied to the light emitting diode, and a current is instantaneously supplied to the light emitting diode, and then the current is cut off. For this reason, the above illumination has the feature that the power loss due to the current limiting resistor can be reduced to further increase the power efficiency, and the circuit configuration can be simplified.

  In addition, the above illumination can emit light strongly by applying a pulse voltage (Vh) higher than the forward voltage (Vs) in the forward direction to the light emitting diode, and further using the eye's refractory period to consume power. As a result, the temperature rise of the light emitting diode is small, and the characteristics that can effectively prevent the life reduction and the light emission efficiency from being lowered due to the temperature rise are also realized. Furthermore, in order to prevent the life of the light emitting diode from suddenly shortening due to temperature rise, it is necessary to prevent the temperature rise by providing a large heat radiation fin, etc., but the above lighting has a small temperature rise of the light emitting diode, It also realizes a feature that can extend the service life while reducing heat dissipation by heat radiating fins. This feature is particularly effective in lighting such as vehicle headlights and projectors. This is because it is used in an environment where strong emission intensity is required and the ambient temperature is high.

  The illumination of the present invention can emit light by applying a pulse voltage having a peak value (Vh) of 1.5 times or more of the forward rising voltage (Vs) of the light emitting diode 1 from the power source 3 to the light emitting diode 1.

  The illumination of the present invention can emit light by applying a pulse voltage (Vh) having a peak value (Vh) that is twice or more the forward rising voltage (Vs) of the light emitting diode 1 from the power source 3 to the light emitting diode 1.

  The illumination of the present invention can emit light by applying a pulse voltage having a peak value (Vh) that is three times or more of the forward rising voltage (Vs) of the light emitting diode 1 from the power source 3 to the light emitting diode 1.

  In the illumination according to the present invention, the light emitting diode 1 can emit light by supplying the light emitting diode 1 with a pulse voltage having a pulse voltage duty of 10% or less. In the above illumination, a pulse voltage with a duty of 10% or less is applied to the light emitting diode, so that the peak value (Vh) of the pulse voltage is applied to a voltage substantially higher than the forward rising voltage (Vs). The light emission color can be shifted from the standard light emission color to the short wavelength side.

  The illumination according to the present invention emits light by applying a pulse voltage (Vh), a pulse width (W), and a pulse voltage with a duty to the light emitting diode 1 from the power source 3 so that the effective current of the light emitting diode 1 is less than the maximum allowable current. Can be made. The above illumination can emit light while protecting the light emitting diode by making the effective current of the light emitting diode smaller than the maximum allowable current.

  The illumination of the present invention can change the emission color of the light emitting diode 1 by changing the peak value (Vh) of the pulse voltage with the pulse generation circuit 4 of the power supply 3. The above illumination has a feature that the peak value (Vh) of the pulse voltage applied to the light emitting diode can be changed to vary the standard emission color emitted by the DC power source.

  In the illumination of the present invention, a pulse generation circuit 4 for changing the pulse voltage peak value (Vh) and the duty is provided in the power supply 3, and the pulse voltage peak value (Vh) is increased to reduce the duty, thereby reducing the light emitting diode 1. Can emit light. The above illumination has a feature that the emission color can be changed greatly while protecting the light emitting diode, because the pulse voltage (Vh) of the pulse voltage is increased and the duty is controlled to be small.

  The illumination of the present invention is provided with a pulse generation circuit 4 for changing the pulse voltage peak value (Vh) and the pulse width (W), and with this pulse generation circuit 4, the pulse voltage peak value (Vh) is increased. Thus, the light emitting diode 1 can be turned on by reducing the pulse width (W). The illumination described above has a feature that the emission color can be changed greatly while protecting the light emitting diode, since the pulse voltage (Vh) is increased and the pulse width (W) is decreased.

  The illumination of the present invention can emit light by applying a pulse voltage of a rectangular wave from the power source 3 to the light emitting diode 1. This illumination has the feature that the light-emitting diode can emit light by simplifying the circuit configuration of the power supply.

  The illumination of the present invention can supply a pulse voltage applied to the light emitting diode from the power source 3 to the light emitting diode 1 as a rectangular wave with overshoot. This illumination has the advantage that the emitted color can be effectively shifted to the short wavelength side by instantaneously accelerating electrons and holes by pulse voltage overshoot. In addition, the peak voltage (Vh) value of the pulse voltage is changed by overshoot, and the feature that the bandwidth of the emission peak can be further widened is realized.

  The illumination according to the present invention is provided with a pulse generation circuit 4 that changes the peak value (Vh) of one pulse, supplies a pulse voltage from the pulse generation circuit 4 to the light emitting diode 1, and the peak value of one pulse of the pulse voltage ( Vh) can be changed to change the emission color of one pulse. Since this illumination changes the peak value (Vh) of one pulse to change the emission color of one pulse, it also realizes the feature that the bandwidth of the emission peak can be made wider.

  The illumination of the present invention is provided with a pulse generation circuit 4 that changes the peak value (Vh) of the pulse voltage at a predetermined cycle, and the peak value (Vh) of the pulse voltage supplied from the pulse generation circuit 4 to the light emitting diode 1 is obtained. By changing it, the emission color of the light emitting diode 1 can be changed in a predetermined cycle. Since this illumination changes the emission color by changing the peak value (Vh) of the pulse voltage at a predetermined period, it also realizes the feature that the bandwidth of the emission peak can be made wider.

  In the illumination of the present invention, a plurality of light emitting diodes 1 are connected in parallel to form a diode unit 2, and a power source 3 can be connected to the diode unit 2 without a current limiting element. This illumination has the feature that a plurality of light emitting diodes can be efficiently emitted with a predetermined luminance without being damaged without using a current limiting element. This is because light can be emitted by applying a pulse voltage to each of the light emitting diodes connected in parallel.

  In the illumination of the present invention, a plurality of sets of diode units 2 having different emission colors are provided, a plurality of sets of light emitting diodes 1 are connected in parallel to each other, and connected to a power source 3 without a current limiting element. The unit 2 has light emitting diodes 1 of the same emission color connected in parallel, and a peak value exceeding the forward rising voltage (Vs) of the light emitting diode 1 with the maximum rising voltage (Vs) in the forward direction from the power supply 3 as the maximum voltage. Light can be emitted by applying a pulse voltage of (Vh) to a plurality of sets of diode units 2. This illumination can emit light from a plurality of light emitting diodes having different emission colors without using a current limiting resistor, and has a feature that power loss due to the current limiting resistor can be eliminated and power efficiency can be improved.

  In the above illumination, the peak value (Vh) of the pulse voltage supplied to the plurality of sets of diode units 2 is controlled by the pulse generation circuit 4, and the peak value (Vh) of the pulse voltage is controlled by this pulse generation circuit 4, The color point of the total emission color of the plurality of sets of diode units 2 can be controlled.

  In the illumination according to the present invention, an output timing for outputting a plurality of pulse voltages in the first cycle, and a pause timing for pausing the output of the pulse voltage after the output timing are set to a second cycle slower than the first cycle. The pulse generation circuit 4 supplies the pulse voltage to the light emitting diode 1 repeatedly, and the pulse generation circuit 4 applies the pulse voltage to the light emitting diode 1 in the first period and the second period to emit light. Can do.

  The above illumination emits light by applying a plurality of pulse voltages to the light emitting diodes at the output timing, and cuts off the current at the pause timing. Therefore, by applying a pulse voltage having a higher peak value (Vh) at the output timing, the emission color Can be shifted from the reference emission color to the shorter wavelength side. In addition, since the effective current of the light emitting diode can be reduced by providing a pause timing, there is a feature that the emission color can be greatly shifted to the short wavelength side by increasing the peak value (Vh) of the pulse voltage without damaging the light emitting diode.

  In the above illumination, the luminance of the light emitting diode 1 can be controlled by controlling either or both of the duty of the first period and the second period by the pulse generation circuit 4. This illumination has a feature that the light emission luminance of the light emitting diode can be controlled by controlling the duty of either or both of the first period and the second period with a pulse generation circuit.

  Furthermore, the above illumination can change the light emission color of the light emitting diode by changing the peak value (Vh) of the pulse output in the first period. This illumination has a feature that the pulse generation circuit controls the pulse peak value (Vh) in the first period to change the emission color, thereby widening the bandwidth of the emission peak.

It is a block diagram of illumination provided with the light emitting diode concerning one Example of this invention. It is a figure which shows an example of the pulse voltage waveform which a power supply outputs. It is a figure which shows another example of the pulse voltage waveform which a power supply outputs. 4A is a diagram showing another example of a pulse voltage waveform output from the power supply, and FIG. 4B is an enlarged view of the pulse voltage waveform shown in FIG. 4A. FIG. 5A is a diagram showing another example of a pulse voltage waveform output from the power supply, and FIG. 5B is an enlarged view of the pulse voltage waveform shown in FIG. 5A. It is a figure which shows an example of the waveform of 1 pulse of a pulse voltage waveform. It is a figure which shows another example of the waveform of 1 pulse of a pulse voltage waveform. It is a figure which shows another example of the waveform of 1 pulse of a pulse voltage waveform. It is a circuit diagram which shows the specific example of the power supply of the illumination concerning the Example of this invention. It is a circuit diagram which shows the other specific example of the power supply of the illumination concerning the Example of this invention. It is a circuit diagram of the conventional light emitting diode illumination. It is a graph which shows the voltage-current characteristic of a light emitting diode. It is a graph which shows the light emission characteristic of a white light emitting diode.

  Embodiments of the present invention will be described below with reference to the drawings. However, the example shown below illustrates the illumination provided with the light emitting diode for embodying the technical idea of the present invention, and the present invention does not specify the illumination as follows. Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The illumination shown in FIG. 1 includes a light emitting diode 1 and a power source 3 connected to the light emitting diode 1. In the illustrated illumination, a plurality of light emitting diodes 1 are connected in parallel and connected to a power source 3. The power source 3 includes a pulse generation circuit 4 that generates a pulse voltage having a peak value (Vh) that exceeds the forward rise voltage (Vs) of the light emitting diode 1, and the pulse generation circuit 4 rises in the forward direction to the light emitting diode 1. A pulse voltage having a peak value (Vh) exceeding the voltage (Vs) is supplied to cause the light emitting diode 1 to emit light.

  In the illumination of FIG. 1, a plurality of light emitting diodes 1 are connected in parallel to form a diode unit 2, and a plurality of sets of diode units 2 are connected in parallel and connected to a power source 3. In the illustrated illumination, a red diode unit 2A in which red light emitting diodes 1A are connected in parallel, a green diode unit 2B in which green light emitting diodes 1B are connected in parallel, and a blue light emitting diode 1C are connected in parallel. The three diode units 2 including the blue diode unit 2C are connected in parallel and connected to the power source 3. This illumination emits light from the three sets of diode units 2 so that the emission color can be white. Although not shown, it is also possible to realize illumination in which white light emitting diodes are connected in parallel and connected to a power source so that the emission color is white. Furthermore, it is also possible to connect the light emitting diodes of the same light emission color in parallel to provide the light emission color illumination of the light emitting diode. Further, in the illumination shown in the figure, all the light emitting diodes are connected in parallel. However, the light emitting diodes can be connected in series to emit light, or can be connected in series and parallel to emit light.

  The light emitting diodes 1 having the same light emitting color have the same forward voltage (Vs) in the forward direction, and can be connected in parallel to pass an equal current. As shown in FIG. 1, the light emitting diodes 1 having different emission colors, that is, the light emitting diodes 1 having different forward rising voltages (Vs) can be connected in parallel or in series to emit light. This is because a pulse voltage having a peak value (Vh) higher than the forward rising voltage (Vs) of the light emitting diode 1 is applied to emit light. 1 applies a pulse voltage to the light emitting diode 1 by the pulse generation circuit 4, and therefore controls the current of the light emitting diode 1 by controlling the duty of the pulse voltage, so that a plurality of light emission colors differ. Light can be emitted without damaging the light emitting diode 1.

  The pulse generation circuit 4 of the power source 3 applies a pulse voltage having a peak value (Vh) exceeding the forward rising voltage (Vs) of the light emitting diode 1 to the light emitting diode 1. The light emitting diode 1 to which a pulse voltage higher than the forward rising voltage (Vs) is supplied has a larger energy for recombination of electrons and holes, and a wavelength shorter than the wavelength specified by the energy gap of the semiconductor material. Lights on. In addition, a large current flows in a state where a pulse having a voltage higher than the rising voltage (Vs) is applied, but the current flows only momentarily, and a decrease in emission intensity due to a temperature increase is reduced by reducing the temperature rise. .

  2 to 5 show the waveform of the pulse voltage supplied from the pulse generation circuit 4 to the light emitting diode 1, and FIGS. 6 to 8 show the waveform of one pulse. In the pulse voltage waveform shown in these drawings, a pulse having a small pulse width (W) is carried to the light emitting diode 1 at a constant cycle. In these figures, the horizontal axis indicates time, and the vertical axis indicates voltage. The pulse voltage waveforms in FIGS. 2 and 3 output pulses at a constant period (T).

  The pulse voltage waveform of FIG. 2 outputs pulses having the same peak value (Vh) at a constant cycle, and the pulse voltage waveform of FIG. 3 outputs pulses having different peak values (Vh) at a constant cycle. The pulses having the same peak value (Vh) shown in FIG. 2 cause the light emitting diode 1 to emit light with the same emission color and intensity. Pulses having different peak values (Vh) shown in FIG. 3 are emitted with different emission colors and intensities. Therefore, the pulse voltage in FIG. 3 can cause the light emitting diode 1 to emit light in a wider wavelength range.

In the pulse voltage waveform shown in FIG. 2 and FIG. 3, the duty (D) and the frequency (f) are specified by the following expression from the period (T) and the pulse width (W).
D = W / T
f = 1 / T

  The pulse voltage waveforms in FIGS. 4 and 5 repeat the output timing and the pause timing at a constant cycle (second cycle), and output a plurality of pulse voltages at the first cycle (T1) at the output timing. In the pause timing, the output of the pulse voltage is paused. The second period (T2) is set longer than the first period (T1). The pulse voltage waveform of FIG. 4 outputs a pulse having the same peak value (Vh) at the output timing, and the pulse voltage waveform of FIG. 5 changes the peak value (Vh) of the pulse output in the first period. Yes. Since the pulse voltage waveform of FIG. 5 changes the peak value (Vh), the emission color of the light emitting diode 1 can be changed at the output timing.

In this pulse voltage waveform, the duty (D) is specified by the following equation from the second period (T2), the pulse width (W), and the number of pulses (n) at the output timing.
D = (W × n) / T2

  As shown in the above figure, the pulse generation circuit 4 generates a pulse having a predetermined pulse width (W) at a constant period with a peak value (Vh) higher than the forward rising voltage (Vs) of the light emitting diode 1. A pulse voltage is supplied to the light emitting diode 1. The light emitting diode 1 to which a pulse voltage having a peak value (Vh) higher than the forward rising voltage (Vs) is supplied emits light shifted to a wavelength shorter than the standard wavelength specified by the energy gap of the conductor material. To do. This is because a pulse voltage higher than the forward rising voltage (Vs) accelerates electrons and holes and increases the energy of recombination in the PN junction layer. In this illumination, the peak value (Vh) of the pulse voltage can be increased to shift the emission color of the light emitting diode 1 from the standard emission color to the shorter wavelength side. Even if a pulse voltage with a high peak value (Vh) increases the light emission intensity by increasing the current of the light-emitting diode 1, the current flows only momentarily and the temperature rise is small, and the light emission efficiency decreases due to the temperature rise. Can be prevented.

  As the peak value (Vh) of the pulse voltage is made higher than the rising voltage (Vs) in the forward direction, the emission color of the light emitting diode 1 is shifted from the standard emission color to the shorter wavelength side, and even if a large current flows. Since the light emission time is short, the temperature rise is small. Therefore, the peak value (Vh) of the pulse voltage is set to an optimum value in consideration of the light emission color and light emission intensity of the light emitting diode 1. The peak value (Vh) of the pulse voltage is set to, for example, 1.5 times or more, preferably 2 times or more, more preferably 4 times or more of the forward rising voltage (Vs) of the light emitting diode 1.

  Further, the maximum peak value (Vh) of the pulse voltage is set to a voltage that does not damage the light emitting diode 1 in consideration of the pulse width (W). The maximum peak value (Vh) can be increased by reducing the pulse width (W). Therefore, for example, the peak value (Vh) of a pulse with a pulse width (W) of 1 μsec is set to 100 times or less, preferably 50 times or less, more preferably 30 times or less of the rising voltage (Vs), and the emission color and emission Strength can be controlled. Further, the pulse voltage can be further increased by setting the pulse width (W) of the pulse to 1 μsec or less and further increasing the maximum peak value (Vh). Further, since the maximum peak value (Vh) varies depending on the characteristics of the light-emitting diode 1, the present invention does not specify the maximum value of the peak value (Vh) of the pulse voltage in the above range, and the light-emitting diode. 1 can be set to a voltage that does not damage.

  The pulse generation circuit 4 supplies a pulse voltage higher than the rising voltage (Vs) in the forward direction, and controls the pulse voltage so that the light emitting diode 1 is not damaged and has a pulse width (W) and a duty voltage. Since the effective current can be reduced by reducing the pulse width (W) and the duty, the pulse generating circuit 4 controls the pulse voltage (Vh), the pulse width (W) and the duty of the light emitting diode 1. Can be made smaller than the maximum allowable current. In the state where the peak value (Vh) is increased and the current increases, the pulse generation circuit 4 decreases the pulse width (W) and decreases the pulse width (W) and the duty to decrease the effective current. .

  The pulse width (W) of the pulse is set longer than the delay time when the light emitting diode 1 is turned on, that is, the time from the pulse rising timing to the light emission timing. If the pulse width (W) is too long, it takes a long time for a large current to flow through the light emitting diode 1 in one pulse, and the light emitting diode 1 is thermally damaged. Therefore, the pulse width (W) of the pulse is preferably 1 msec or less, for example. Is 100 μsec or less, more preferably 10 μsec or less. The pulse width (W) of the pulse voltage is set larger than the minimum value at which the light emitting diode 1 can emit light. Therefore, the pulse width (W) is set larger than the delay time of the light emitting diode 1.

  The light-emitting diode 1 can emit light efficiently with a pulse having a pulse width (W) of 1 μsec or less because the delay time until the light-emitting diode 1 is lit by supplying a voltage is as short as 100 nsec or less. Further, when the pulse voltage period is made constant and the pulse width (W) is shortened, the duty is reduced, so that the effective current can be reduced. The effective current flowing through the light-emitting diode 1 increases as the peak value (Vh) of the pulse voltage increases, decreases as the pulse width (W) of the pulse decreases, and decreases as the duty decreases. Therefore, the duty of the pulse voltage is set to an optimum value according to the peak value (Vh) and the pulse width (W) of the pulse voltage, and is, for example, 10% or less, preferably 3% or less, more preferably 1% or less. .

  For example, a blue light-emitting diode 1 made of gallium nitride has a peak value (Vh) of 10 V (about four times the rising voltage in the forward direction), a pulse width (W) of 1 μsec, a pulse period of 1 KHz, and a duty of 0.1. When a pulse voltage of% is applied, the emission color changes from standard blue to purple, and light is emitted efficiently. In addition, when a pulse voltage with a peak value (Vh) of 10 V, a pulse width (W) of 1 μsec, a pulse period of 1 KHz, and a duty of 0.1% is applied to the green light emitting diode 1, the emission color changes from green. It changes to a deeper green.

  The pulse generation circuit 4 controls and outputs the pulse voltage so that the effective current of the light emitting diode 1 is smaller than the maximum current allowed for the light emitting diode 1. Since the effective current of the light emitting diode 1 is specified by the pulse voltage peak value (Vh), the pulse width (W), the pulse frequency, and the duty as described above, the pulse voltage peak value (Vh). , The pulse width (W) is increased, the pulse frequency is decreased, that is, the duty is increased, and the effective current of the light emitting diode 1 is increased. Therefore, the pulse generation circuit 4 that increases the peak value (Vh) of the pulse voltage controls the pulse generation circuit 4 so that the effective current does not exceed the maximum current by reducing the pulse width (W) and duty of the pulse voltage. .

  If the period of the pulse voltage is too long and the frequency at which the light-emitting diode 1 is lit is too low, flickering occurs when the pulse voltage is used for illumination. Therefore, the pulse period, that is, the frequency of the pulse voltage waveform is set higher than 30 Hz, preferably higher than 60 Hz, more preferably higher than 100 Hz, and optimally higher than 500 KHz. As the frequency of the pulse voltage increases and the period decreases, the duty increases and the effective current increases. Therefore, the cycle of the pulse voltage, that is, the frequency is set to, for example, 10 KHz or less, preferably 5 KHz or less, and more preferably 3 KHz or less.

  6 to 8 show pulse waveforms. Since the pulses in FIG. 6 are rectangular waves and have the same peak value (Vh), the light emission color of the light emitting diode 1 does not change in a state where the pulses are supplied. The pulse in FIG. 7 is a rectangular wave with an overshoot that increases the peak value (Vh) at the rise timing of the pulse. The light emitting diode 1 to which this pulse is applied is instantaneously supplied with a high voltage with an overshoot of the rising timing of the pulse. Therefore, at the rising edge of the pulse, electrons and holes are accelerated to a larger energy and the emission color is shifted to the short wavelength side, and then the wavelength of the emission color is increased by decreasing to the peak value (Vh) of the rectangular wave. Become. The pulse in FIG. 8 gradually decreases after the peak value (Vh) peaks at the rising timing. Since the voltage of this pulse decreases with time, the pulse width (W) reaches 0 V and becomes the maximum value (Wmax). The light emitting diode 1 that emits light with this pulse changes its emission color gradually from the standard emission color to the short wavelength side at the rising timing and then gradually approaches the standard emission color.

  6 and 7 can be generated by an oscillation circuit such as an astable multivibrator, a timer IC, or a digital circuit. The pulse voltage set from the oscillation circuit is amplified by the power amplification circuit and supplied to the light emitting diode 1 as a pulse voltage having a predetermined peak value (Vh). The pulse generation circuit 4 of the power supply 3 includes an oscillation circuit and a power amplification circuit. The pulse voltage shown in FIG. 7 is obtained by providing an overshoot to the rectangular wave output from the oscillation circuit with a coupling capacitor, an integration circuit, or the like and outputting it to the power amplifier circuit. Further, the pulse voltage of FIG. 8 can be realized by a power supply 3B in which a coupling capacitor 7 is connected between the oscillation circuit 5 and the power amplifier circuit 6, as shown in FIG. The oscillation circuit 5 can adjust the characteristic that gradually decreases from the peak value (Vh) of the peak due to the capacitance of the coupling capacitor 7, and the capacitance of the coupling capacitor 7 is reduced to have a steep drop characteristic. it can. Therefore, the capacitance of the coupling capacitor 7 can be reduced and the energy of one pulse can be reduced. Therefore, as shown in FIG. 10, the illumination for supplying a pulse voltage to a plurality of sets of diode units 2 has a power amplifying circuit 6 in which coupling capacitors 7 having different capacitances are connected to the input side. The diode unit 2 can emit light by supplying optimum power. Since the power supply 3C can control the power supplied to the electrostatic capacitance diode unit 2 by the coupling capacitor 7, it has a feature that it can supply the optimum power to the light emitting diode 1 with a simple circuit. However, the power of the light emitting diode connected to the power amplifier circuit connected to the oscillation circuit can be controlled by controlling the peak value (Vh) and pulse width (W) of the rectangular wave oscillating in the oscillation circuit. Needless to say. A power supply including an oscillation circuit of a digital circuit can output a pulse voltage peak value (Vh), a pulse width (W), and a period by software to a light emitting diode from a power amplifier circuit.

  The lighting of the present invention is effective for indoor and outdoor lighting fixtures, back lighting for display panels such as liquid crystal, car lighting such as car headlights and interior lighting, signage and decoration lighting, and projector light sources. Can be used for

DESCRIPTION OF SYMBOLS 1 ... Light emitting diode 1A ... Red light emitting diode 1B ... Green light emitting diode 1C ... Blue light emitting diode 2 ... Diode unit 2A ... Red diode unit 2B ... Green diode unit 2C ... Blue diode units 3, 3B, 3C ... Power supply 4 ... Pulse generation circuit 5 ... oscillation circuit 6 ... power amplification circuit 7 ... coupling capacitor 91 ... light emitting diode 93 ... DC power supply 98 ... current limiting resistor

Claims (19)

An illumination comprising a light emitting diode comprising a light emitting diode and a power source connected to the light emitting diode,
The power source includes a pulse generation circuit that generates a pulse voltage having a peak value (Vh) exceeding a forward rising voltage of the light emitting diode;
An illumination comprising a light emitting diode, wherein the pulse generation circuit supplies the light emitting diode with a pulse voltage having a peak value (Vh) exceeding a forward rising voltage (Vs). An illumination comprising the light emitting diode according to claim 1,
The power source includes a light emitting diode that emits light by applying to the light emitting diode a pulse voltage having a peak value (Vh) of 1.5 times or more of a forward rising voltage (Vs) of the light emitting diode. illumination. An illumination comprising the light emitting diode according to claim 1,
An illumination including a light emitting diode, wherein the power source applies a pulse voltage having a peak value (Vh) that is twice or more a forward rising voltage (Vs) of the light emitting diode to the light emitting diode to emit light. An illumination comprising the light emitting diode according to claim 1,
An illumination comprising a light emitting diode, wherein the power source applies a pulse voltage having a peak value (Vh) of three times or more of a forward rising voltage (Vs) of the light emitting diode to the light emitting diode to emit light. An illumination comprising the light-emitting diode according to any one of claims 1 to 4,
An illumination comprising a light emitting diode whose duty cycle of a pulse voltage applied to the light emitting diode by the power source is 10% or less. An illumination comprising the light-emitting diode according to any one of claims 1 to 5,
The pulse generation circuit applies a peak voltage (Vh), a pulse width (W), and a duty pulse voltage that make the effective current of the light emitting diode not more than a maximum allowable current to the light emitting diode. Lighting with a light emitting diode. An illumination comprising the light-emitting diode according to any one of claims 1 to 6,
The power source includes a pulse generation circuit that changes a peak value (Vh) of a pulse voltage,
An illumination comprising a light emitting diode, wherein the pulse generation circuit controls a light emission color of the light emitting diode by changing a peak value (Vh) of a pulse voltage. Lighting comprising the light-emitting diode according to claim 7,
The power source includes a pulse generation circuit that changes a peak value (Vh) and a duty of a pulse voltage,
The illumination with the light emitting diode, wherein the pulse generation circuit increases the peak value (Vh) of the pulse voltage to reduce the duty. Lighting comprising the light-emitting diode according to claim 7,
The power source includes a pulse generation circuit that changes a peak value (Vh) and a pulse width (W) of a pulse voltage,
The illumination including a light emitting diode, wherein the pulse generation circuit increases a peak value (Vh) of a pulse voltage to reduce a pulse width (W). An illumination comprising the light-emitting diode according to claim 1,
An illumination comprising a light emitting diode, wherein the power supply applies a pulse voltage of a rectangular wave to the light emitting diode. Lighting comprising the light emitting diode according to claim 10,
An illumination comprising a light emitting diode in which a pulse voltage applied to the light emitting diode by the power source is a rectangular wave having an overshoot. An illumination comprising the light-emitting diode according to claim 1,
The power source includes a pulse generation circuit that changes a peak value (Vh) of one pulse,
An illumination comprising a light emitting diode, wherein the pulse generation circuit changes a peak value (Vh) of one pulse to change an emission color of one pulse. An illumination comprising the light-emitting diode according to any one of claims 1 to 12,
The power source includes a pulse generation circuit that changes a peak value (Vh) of a pulse voltage at a predetermined cycle,
An illumination having a light emitting diode, wherein the pulse generation circuit changes a peak value (Vh) of a pulse voltage to change a light emission color of the light emitting diode at a predetermined cycle. An illumination comprising the light-emitting diode according to claim 1,
A diode unit comprising a plurality of light emitting diodes connected in parallel,
An illumination comprising a light emitting diode in which the power source is connected to the diode unit without a current limiting element. Lighting comprising the light emitting diode according to claim 14,
A plurality of sets of diode units having different emission colors are provided, and the plurality of sets of light emitting diodes are connected in parallel to each other and connected to the power source without a current limiting element,
Each set of diode units is connected in parallel with light emitting diodes of the same emission color,
The power supply applies a pulse voltage having a peak value (Vh) exceeding a forward rising voltage (Vs) of a light emitting diode whose maximum voltage is a forward rising voltage (Vs) to a plurality of sets of diode units. Lighting with a light emitting diode. Lighting comprising the light emitting diode according to claim 15,
A pulse generation circuit for controlling a peak value (Vh) of a pulse voltage supplied from the power source to the plurality of sets of the diode units;
An illumination including a light emitting diode in which the pulse generation circuit controls a peak value (Vh) of a pulse voltage to control a color point of a total light emission color of a plurality of diode units. Lighting comprising a light emitting diode comprising the light emitting diode according to any one of claims 1 to 10,
The power supply repeats an output timing at which a plurality of pulse voltages are output in the first cycle and a pause timing at which the output of the pulse voltage is paused after the output timing in a second cycle that is slower than the first cycle. A pulse generation circuit for supplying a pulse voltage to the light emitting diode,
An illumination comprising a light emitting diode, wherein the pulse generation circuit emits light by applying a pulse voltage to the light emitting diode in a first period and a second period. Lighting comprising the light emitting diode according to claim 17,
An illumination comprising a light emitting diode, wherein the pulse generator circuit of the power supply controls the luminance of the light emitting diode by controlling either or both of the duty of the first period and the second period. Lighting comprising the light emitting diode according to claim 17 or 18,
The illumination including a light emitting diode, wherein the pulse generation circuit changes a peak value (Vh) of a pulse output in the first period to change a light emission color of the light emitting diode.

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