JP2001313423A - Light-emitting diode drive device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a light-emitting diode drive device, in which the stability of a light-emitting diode current is superior, has reduced power loss and input current strains and which is comparatively low-cost. SOLUTION: A light-emitting diode LED is driven by the DC output of a step-up chopper BUT which is provided with an inductor L, a switching element Q and a diode D (also a light-emitting diode can be used). The feedback circuit LFC of the light-emitting diode current flowing in the light-emitting diode LED is installed. According to its detection signal, the control circuit CC of the step-up chopper BUT is controlled, in such a way that the light-emitting-diode current is averaged as seen in a time region, which is longer than the cycle of a low-frequency alternating current. The switching element Q is controlled to be turned on, when the inductor discharges energy. The switching element Q is controlled to be turned off according to whether a switching current value or after a prescribed time elapsed, after the switching element Q is controlled to be turned on.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light emitting diode driving device for driving a light emitting diode with direct current.

[0002]

2. Description of the Related Art Conventionally, when driving a light emitting diode,
It is common to connect a current limiting element in series with the light emitting diode. Hereinafter, a conventional light emitting diode driving device will be described with reference to FIGS. In the drawings, the same portions are denoted by the same reference numerals.

FIG. 5 is a circuit diagram showing a first example of a conventional light emitting diode driving device.

In FIG. 1, reference numeral 111 denotes an AC power supply, 112 denotes a light emitting diode group, and 113 denotes a current limiting element.

[0005] The light emitting diode group 112 includes a first light emitting diode 112a and a second light emitting diode 112b which are connected in opposite polarities. Then, the first light emitting diode 112a is driven when the AC power supply 111 has a positive polarity. The second light emitting diode 112b is driven when the AC power supply 111 has a negative polarity.

The current limiting element 113 comprises a resistor,
The input current flowing through the light emitting diode group is limited to a predetermined value at any polarity of the power supply voltage.

FIG. 6 is a circuit diagram showing a second example of a conventional light emitting diode driving device.

In a second example, the current limiting element 113 is formed by a capacitor.

FIG. 7 is a circuit diagram showing a third example of a conventional light emitting diode driving device.

In a third example, a low-frequency alternating current is supplied to a full-wave rectifier 11.
4 and a smoothing capacitor 115, and the DC is converted to a high frequency by a high frequency inverter 116, and the light emitting diode group 112 is driven at a high frequency. An inductor is used for the current limiting element 113. In addition, 117 is a high frequency filter, and 118 is a DC cut capacitor. The high frequency inverter 11
Reference numeral 6 denotes a half-bridge type inverter mainly composed of a pair of switching elements 116a and 116b and a gate drive circuit 116c.

FIG. 8 is a circuit diagram showing a fourth example of a conventional light emitting diode driving device.

In a fourth example, a step-up chopper 119 and a step-down chopper 120 are used. In addition, the current flowing through the light emitting diode group 112 ′ is detected by the resistor 121, is compared with the reference voltage source 123 by the operational amplifier 122, and is input to the pulse width modulation (PWM) circuit 124 so as to be controlled. Is a current feedback control. Therefore, the light emitting diode group 112 'can be driven by the stabilized DC. Note that the light emitting diode group 112 'is not connected to the opposite polarity because of the DC drive. The boost chopper 119 includes an inductor 119
a, switching element 119b, diode 119c,
Smoothing capacitor 115 and gate drive circuit 119
d is mainly composed. Further, the step-down chopper 120 includes a switching element 120a, a diode 12
0b, inductor 120c and gate drive circuit 1
20d.

Next, referring to FIGS. 9 to 11, the waveforms of the power supply voltage and the waveform input current of the LED driving device in each of the conventional examples will be described. In the figure, V
Indicates a power supply voltage waveform, and I indicates an input current waveform.

FIG. 9 is a waveform diagram showing the waveforms of the power supply voltage and the input current in the first example of the conventional light emitting diode driving device.

FIG. 10 is a waveform diagram showing waveforms of a power supply voltage and an input current in a second example of the conventional light emitting diode driving device.

FIG. 11 is a waveform diagram showing waveforms of a power supply voltage and an input current in a fourth example of the conventional light emitting diode driving device.

[0017]

The first example has the advantage that the circuit configuration is simple, but the power loss of the resistor is large, the energy efficiency as a light source is low, and the input current has many harmonics. There's a problem. That is, as can be understood from FIG. 9, in the first example, since a pause period occurs in the input current near the zero crossing of the power supply voltage, harmonics increase.

The second example has a simple circuit configuration and eliminates the problem of power loss in the current limiting element 113 as in the first example, but has poor current stability. Further, as can be understood from FIG. 10, there is a problem that both the power factor and the harmonics deteriorate because the waveform deteriorates as the phase of the input current advances.

The third example is similar to the second example in that a reactive element having no power loss can be used for the current limiting element 113, and furthermore, the phase of the input current is made the same as the phase of the power supply voltage. be able to. However, there is a problem that a rest period substantially similar to the case of Example 1 shown in FIG. 9 occurs near the zero crossing of the input current, and therefore, there is a problem that harmonics increase.

In the fourth example, since the boost chopper 119 can be configured to act as a power factor correction (PFC) circuit, the input current waveform can be made substantially similar to the power supply voltage waveform. However, there is a problem that it is complicated and the cost increases.

In contrast to the above prior art, Japanese Patent Laid-Open No. 11-6 / 1999
No. 7471 discloses an illumination device configured to directly drive a light emitting diode with a DC output of a step-up chopper. (Prior art 5) The light emitting diode driving device described in this prior art 5 is relatively inexpensive, has a small power loss due to a current limiting element, and has no idle period of an input current, so that harmonic distortion is small. It has advantages and provides a practically superior light emitting diode drive. In the prior art 5, a series circuit of the resistor 40 and the variable resistor 41 is connected in parallel with the smoothing capacitor 39 connected between the output terminals of the boost chopper, and the voltage at the connection point is fed back to the control circuit 44. Thus, the ripple of the smoothing capacitor p39 is suppressed. That is, constant voltage control is performed. Since the current / voltage characteristics of the light emitting diode change according to the temperature, there is a slight difficulty in the stability of the light emitting diode current flowing through the light emitting diode.

An object of the present invention is to provide a relatively inexpensive light emitting diode driving device which has excellent stability of the light emitting diode current, low power loss and low input current distortion.

[0023]

According to a first aspect of the present invention, there is provided a light emitting diode driving apparatus comprising: a rectified DC power supply having an AC input terminal connected to a low-frequency AC power supply; The inductor and the switching element connected to the diode, the diode connected in series with the light emitting diode of the load between both ends of the switching element, and the switching element is turned on when the energy stored in the inductor is released, and after a predetermined time, A step-up chopper having a control circuit for turning off the switching element; a light-emitting diode driven by a DC output of the step-up chopper as a load of the step-up chopper; a light-emitting diode current flowing through the light-emitting diode is detected and returned to the control circuit. Light emitting diode current is averaged when viewed in a time region longer than the period of low frequency AC It is characterized in that it comprises a; light-emitting diode current feedback circuit for controlling the step-up chopper control circuit so as to.

In the present invention and each of the following inventions, definitions and technical meanings of terms are as follows unless otherwise specified.

As the low-frequency AC power supply, a commercial AC power supply or the like can be used, and “low frequency” is relative to the operating frequency of the boost chopper.

<Regarding Rectified DC Power Supply> A rectified DC power supply inputs AC and outputs DC. Typically, a full-wave rectifier circuit can be used, but the present invention is not limited to this. In addition, by configuring the control circuit to appropriately change the on / off time of the switching element of the boost chopper according to the instantaneous value of the input power supply voltage, an input current waveform similar to the power supply voltage waveform is obtained. Since a high power factor and low harmonic distortion can be realized, the rectified DC power supply may output non-smooth DC. Therefore, it is not necessary to provide a smoothing means such as a smoothing capacitor in addition to the boosting chopper.

<Regarding Boost Chopper> The boost chopper includes an inductor, a switching element, a diode, and a control circuit as constituent elements. The switching element may be any of a voltage drive type such as an FET and a current drive type such as a bipolar transistor. Since the diode uses a light emitting diode as a load, the diode can also be used as a load.

The control circuit controls on / off of the switching element. And it has a drive signal generation part and a control part. A drive signal having a predetermined cycle and phase is generated and supplied to the switching element to turn on the switching element. When the switching element is turned off, the drive signal is cut off.

In the boost chopper, when the switching element is turned on, an increased current flows from the rectified DC power supply to the series circuit of the inductor and the switching element, and electromagnetic energy is accumulated in the inductor. When the drive signal from the control circuit stops, the switching element turns off. At the same time, the energy stored in the inductor is released, a reduced current flows from the inductor to a series circuit of diodes (light emitting diodes) including a load in series, and a boosted voltage appears between the output terminals.

Through the above operation, when the on-time of the switching element of the boost chopper is Ton, the off-time is Toff, the input voltage is Vin, and the output voltage is Vout, the boosted chopper is higher than the input voltage which substantially satisfies the following equation. Output voltage.

Vout = Vin (Ton + Toff) / Toff Next, the switching element is turned on again when the energy stored in the inductor is released through the diode (light emitting diode). Therefore, in the present invention, the boost chopper operates in the discontinuous or current critical mode.

To turn on the switching element again when the release of the energy of the inductor is completed, the drive signal may be generated by monitoring the terminal voltage of the inductor. This is because the terminal voltage of the inductor changes in a step-like manner when the energy of the inductor ends to be released. By monitoring this, the end of the energy release of the inductor can be detected. In order to monitor the terminal voltage of the inductor, a detection winding is magnetically coupled to the inductor, and the output is controlled and input to the control circuit directly or, if necessary, via a waveform shaping circuit. However, since the voltage across the switching element also changes at the same time as the step-like voltage change occurs in the inductor, the voltage across the switching element may be monitored instead of the terminal voltage of the inductor.

If necessary, a smoothing capacitor can be connected between the output terminals of the step-up chopper. That is, in the present invention, the diode and the smoothing capacitor are not essential components of the boost chopper. However, when the same average current flows through the light emitting diode by connecting the smoothing capacitor, the effective value can be reduced.

The operating frequency of the step-up chopper is set in a high frequency region relatively higher than the frequency of the low frequency alternating current.
Its operating frequency is determined by the inductance of the inductor. In practice, it is preferable to set the operating frequency so as not to be in the audible frequency range. Further, as can be understood from the above equation, the duty ratio changes over the period of the low-frequency AC according to the instantaneous value of the input voltage and the output voltage.

The output voltage of the boost chopper is set to a required value according to the number of light emitting diodes connected in series.

<Regarding Light Emitting Diode> On the other hand, when viewed from the light emitting diode side, the number of connected light emitting diodes can be set to one or more in accordance with the output voltage of the boosting chopper. The sum of the forward voltages of the respective light emitting diodes can be set to be equal to the output voltage of the boost chopper.

The emission color of the light emitting diode and the forward voltage are not limited.

<Regarding Light Emitting Diode Current Feedback Circuit>
The light emitting diode current feedback circuit detects the light emitting diode current flowing through the light emitting diode, and controls the boost chopper to average the light emitting diode current when the control circuit sees the light emitting diode current in a time region longer than the period of the low-frequency AC. To help. In order to perform such control, it is preferable to provide an integrating means in the system of the light emitting diode feedback circuit in order to suppress a circuit operation faster than a low frequency.

<Operation of the Present Invention> Since the light emitting diode current feedback circuit is provided and the control circuit is controlled by the feedback signal, the light emitting diode current is averaged when the light emitting diode current is viewed in a time region longer than the period of the low-frequency alternating current. Thus, even if the current-voltage characteristics change due to a change in the ambient temperature of the light emitting diode, the light emitting diode current is kept substantially constant. For this reason, the stability of the light emitting diode current with respect to power supply voltage and temperature changes is improved, and fluctuation of the diode current due to disturbance can be substantially eliminated.

2. In addition, the following operation similar to that of the related art 5 is exerted.

Since the boosting chopper boosts and outputs the rectified voltage of the low-frequency AC voltage and applies the output voltage to the light emitting diodes to drive the light emitting diodes, the number of connected light emitting diodes can be increased.

The input current has almost no sinusoidal waveform with no pause. For this reason, the standard of the harmonic current for the lighting fixture is satisfied with a margin.

Since the control circuit can be configured using a commercially available power factor improving IC, it can be obtained at relatively low cost.

According to a second aspect of the present invention, there is provided a light emitting diode driving apparatus according to the first aspect, wherein:
The light emitting diode current feedback circuit includes a light emitting diode current detector, an error amplifier that inputs a detection signal output from the light emitting diode current detector to one control input terminal to generate a feedback signal, and the other control input terminal of the error amplifier. , And an integration circuit for forming an integrated feedback signal.

The present invention specifies a preferred configuration example of the light emitting diode current feedback circuit.

The light-emitting diode current detecting circuit can be configured to detect a light-emitting diode current by inserting a resistor in series with the light-emitting diode and taking out a voltage drop occurring there, for example.

The error amplifier has a pair of control input terminals. The output of the light-emitting diode current detection circuit is control-input to one of the control input terminals. Further, a reference potential source is control-input to the other control input terminal.

The integrating circuit can be integrally formed with the error amplifier by connecting it between one control input terminal and the output terminal of the error amplifier. However, the integration circuit can be inserted separately from the error amplifier, for example, between the error amplifier and the control circuit.

Thus, in the present invention, the light emitting diode current is detected by the light emitting diode current detector, and the detection signal is input to one control input terminal of the error amplifier. A reference potential source is connected to the other control input terminal of the error amplifier to control-input the reference potential. Therefore, when the level of the detection signal exceeds the reference potential, the error amplifier has a low level due to the integration action of the integration circuit. The value of the feedback signal changes with a delay so that the response does not become faster than the cycle of the frequency alternating current. The feedback signal is control-input to the control circuit to control the timing of the cutoff of the drive signal of the switching element. Thereby, the timing at which the switching element is turned off is advanced, and the operation is performed so that the load current matches the reference value.

According to a third aspect of the present invention, there is provided a light emitting diode driving device according to the second aspect.
The reference potential source is characterized in that the reference potential is variable.

In the present invention, since the reference potential input to the other control input terminal of the error amplifier can be changed, dimming control can be performed from outside using this function. That is, when the reference potential is lowered in response to a dimming control signal from an external reference, the switching element is quickly turned off, so that the output voltage of the boost chopper is reduced, the light emitting diode current flowing through the light emitting diode is reduced, and the light emission is reduced. The amount is reduced.

Further, the reference potential can be changed for the purpose of compensating the temperature characteristic inside the light emitting diode driving device.

According to a fourth aspect of the present invention, there is provided a light emitting diode driving apparatus according to any one of the first to third aspects, wherein the control circuit detects a current flowing through the switching element and turns off the switching element. Is provided with a switching current detection circuit for controlling the switching current.

The present invention defines a structure for controlling the switching element to be turned off. That is, a switching current detection circuit for detecting an instantaneous current flowing through the switching element for turning off the switching element is provided.
The switching current detection circuit controls and inputs the detection signal to the control circuit. The control circuit receives the detection signal of the switching current detection circuit and stops the drive signal for the switching element. Therefore, the switching element is turned off.

The switching element is turned off at the time when the instantaneous current flowing through the switching element reaches a value obtained by multiplying the absolute value of the low-frequency AC voltage by a proportional constant determined by the switching current feedback circuit.

Thus, in the present invention, since the switching current is detected and the drive signal to the switching element is cut off according to the detected value, there is no possibility that an overcurrent flows through the switching element and the switching current is proportional to the input voltage waveform. The input current waveform can be obtained.

According to a fifth aspect of the present invention, in the light emitting diode driving device according to any one of the first to third aspects, the control circuit switches the switching element when a predetermined time has elapsed since the switching element was turned on. It is characterized in that it is configured to be turned off.

According to the present invention, a configuration different from that of the second aspect for controlling the switching element to be turned off is defined. That is, the control circuit is configured to stop the drive signal of the switching element when a predetermined time has elapsed after the switching element is turned on.

Therefore, in the present invention, a current detection circuit for obtaining a timing for turning off the switching element is not required, and the circuit configuration is simplified.

[0060]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a circuit diagram showing a first embodiment of a light emitting diode driving device according to the present invention.

In the figure, AS is a low-frequency AC power supply, HF
Is a high frequency filter, RDC is a rectified DC power supply, BUT is a step-up chopper, LED is a light emitting diode, LFC is a light emitting diode current feedback circuit, SD is a switching current detecting circuit, LD is an inductor current detecting circuit, and VD is a power supply voltage detecting circuit. is there.

<Regarding Low Frequency AC Power Supply AS> The low frequency AC power supply AS is a commercial AC power supply.

<Regarding High Frequency Filter HF> The high frequency filter HF is composed of a high frequency rejection type filter circuit.
Then, the high frequency generated by the high frequency switching operation of the boost chopper is prevented from flowing out to the low frequency AC power supply AS.

<Regarding Rectified DC Power Supply RDC> The rectified DC power supply RDC is mainly composed of a full-wave rectifier circuit. Then, the low-frequency AC voltage is rectified to output a non-smoothed DC voltage.

<Regarding Step-Up Chopper BUT> The step-up chopper BUT mainly includes an inductor L, a switching element Q, a diode D, and a control circuit CC.

The inductor L is connected in series with the switching element Q between the DC output terminals of the rectified DC power supply RDC.

The switching element Q is composed of a MOSFET.

The diode D is connected in parallel with the switching element Q in series with the light emitting diode LED.

The control circuit CC includes a drive signal generation circuit D
C, a bistable multivibrator BM, a comparison circuit CP, and a multiplier M. Note that the bistable multivibrator
BM, comparison circuit CP and multiplier M constitute a control unit.
Then, a drive signal is applied to the gate of the switching element Q to turn it on, and the drive signal is cut off to turn off the switching element Q. The drive signal generation circuit DC generates a drive signal and applies it to the gate of the switching element Q. Bistable multivibrator BM
Controls the timing of generation and cutoff of the drive signal of the drive signal generation circuit DC. The comparison circuit CP compares the respective signals sent from the switching current detection circuit SD and the multiplier M, which will be described later, and if the switching current detection circuit is larger, the multivibrator B
Send a reset signal to M. The multiplier M multiplies a power supply voltage obtained from a power supply voltage detection circuit VD described later by an output signal of the light-emitting diode current feedback circuit LFC, and sends the result to one control input terminal of the comparison circuit CP.

<Regarding Light-Emitting Diode Current Feedback Circuit LFC> The light-emitting diode current feedback circuit LFC includes a light-emitting diode current detector LD, an error amplifier EA, and a reference potential source E.
And an integrating circuit ICC. The light emitting diode current detector LD includes a resistor inserted in series with the light emitting diode LED. The error amplifier EA is composed of an operational amplifier, has a pair of control input terminals, one of which is supplied with the output voltage of the light emitting diode current detector LD via a series resistor, and the other input terminal of which is connected to the reference potential source E. Have been. The integration circuit ICC is composed of a capacitor connected between one control input terminal and the output terminal of the error amplifier EA.

<Regarding Switching Current Detection Circuit SD> The switching current detection circuit SD includes a resistor inserted between the source of the switching element Q and the negative electrode of the rectified DC power supply RDC, and detects the current flowing through the switching element Q. I do. Then, the detection signal is input to the other control input terminal of the comparator CP.

<Regarding Power Supply Voltage Detection Circuit VD> The power supply voltage detection circuit VD is composed of a resistor voltage divider connected between the DC output terminals of the rectified DC power supply RDC, and outputs the output signal to the other input terminal of the multiplier M. Connected to

<About the inductor current detection circuit LD>
The inductor current detection circuit LD includes a detection winding magnetically coupled to the inductor L, and controls and inputs to the bistable multivibrator BM of the control circuit CC.

<Circuit operation> Light emitting diode LE
The current flowing through D is a light emitting diode current feedback circuit LFC
Is detected by the light emitting diode current detector LD, and is compared with the reference potential source E by the error amplifier EA.
C suppresses a response faster than the cycle of the low-frequency AC, and then controls the bistable multivibrator BM via the multiplier M and the comparator CP to generate a drive signal generation circuit D.
C is given a drive signal cutoff timing. As a result, the switching element Q is turned off. In this circuit operation, the feedback of the light emitting diode current is performed, and the off timing of the switching element Q is adjusted. Therefore, when the light emitting diode current is viewed in a time region longer than the period of the low-frequency AC, the average value thereof is It is controlled to be constant.

Further, the power supply voltage fluctuation is compensated for by the constant current action by the current feedback circuit as described above.

FIG. 2 is a waveform diagram showing waveforms of voltages and currents of respective parts in the first embodiment of the light emitting diode driving device of the present invention.

In the figure, I _SW is an increasing current. That is, when the switching element Q is first turned on by a starting circuit (not shown), the increasing current I linearly increases from the rectified DC power supply RDC via the inductor L.
_SW flows through the switching element Q. At this time, electromagnetic energy is stored in the inductor L.

The increase current I _SW is detected by the switching current detection circuit SD, triggers the monostable multivibrator UM via the comparison circuit CP, and controls the drive signal generation circuit DC to cut off the drive signal. Therefore, the switching element Q is turned off.

_ID is the decreasing current. That is, when the switching element Q is turned off, the electromagnetic energy stored in the inductor L is released,
The current flows out of the inductor L while decreasing linearly through the diode D and the light emitting diode LED.

[0081] _{I L} is an inductor current. That is,
The increasing current I _SW and the decreasing current _ID continuously flow through the inductor L.

V _SW is a voltage appearing across the switching element Q, _VIN is an input voltage, and _VL is a voltage appearing across the inductor L.

FIG. 3 is a waveform diagram showing the waveforms of the inductor current and the voltage of the switching element near the peak value of the power supply voltage and near the zero crossing in the first embodiment of the light emitting diode driving device of the present invention.

[0084] In Figure, (a) represents the inductor current I _L of the waveform at the peak value near the power supply voltage, (b) the inductor current I _L of the waveform at the zero-crossing near the power supply voltage, (c) the voltage of the switching element V _SW waveforms are shown.

As can be understood from the figure, the switching element Q is turned on at the timing when the decreasing current _ID becomes zero, and turned off when the increasing current _ISW is obtained by multiplying the absolute value of the low-frequency AC power supply voltage by a proportional constant. The on-time is almost constant since the operation is performed at the timing when the value reaches the value, but the off-time varies because it is related to the absolute value of the instantaneous value of the low-frequency AC power supply voltage.

FIG. 4 is a circuit diagram showing a second embodiment of the light emitting diode driving device according to the present invention.

In the figure, the same parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. The present embodiment is mainly different in that a monostable multivibrator UM is used instead of the bistable multivibrator BM of the switching current detection circuit and the control circuit CC of the boost chopper BUT.

That is, the control circuit CC comprises a drive signal generation circuit DC and a monostable multivibrator UM. The inductor current detection circuit LD includes a waveform shaping circuit WS for shaping the waveform of the output of the detection winding magnetically coupled to the inductor L.

Thus, in this embodiment, the detection signal of the inductor current detection circuit LD is shaped by the waveform shaping circuit WS, and then triggers the monostable multivibrator UM constituting the control circuit CC. Thus, the monostable multivibrator UM is inverted. Accordingly, the drive signal generation circuit DC generates a drive signal and applies it to the switching element Q, so that the switching element Q is turned on.

The monostable multivibrator UM automatically reverses and returns to its original state when a predetermined time has elapsed after the trigger, so that the drive signal generation circuit DC cuts off the drive signal. As a result, the switching element Q is turned off.

The output of the error amplifier EA of the light emitting diode current feedback circuit LFC adjusts the return time of the monostable multivibrator UM of the control circuit CC, so that the light emitting diode current is averaged.

[0092]

According to the first to fifth aspects of the present invention, the light emitting diode is driven by the DC output of the boosting chopper, and the light emitting diode current feedback circuit flowing through the light emitting diode is provided, and the boosting is performed according to the detection signal. By controlling the chopper control circuit to average the LED current when viewed in a time region longer than the period of the low-frequency AC, the stability of the LED current is excellent and the power loss is reduced. Since the input current does not have a quiescent period, harmonic distortion of the input current is small, and a relatively inexpensive LED driving device can be provided.

According to the second aspect of the present invention, the light emitting diode current feedback circuit further includes the light emitting diode current detecting circuit, the error amplifier, the reference potential source, and the integrating circuit. It is possible to provide a light emitting diode driving device including a diode current feedback circuit.

According to the third aspect of the present invention, since the reference potential of the reference potential source is variable, light emission can be externally controlled or temperature characteristics can be internally compensated. A diode driving device can be provided.

According to the fourth aspect of the present invention, a switching current detecting circuit for controlling the control circuit of the boost chopper so as to turn off the switching element by detecting the switching current flowing through the switching element is provided. It is possible to provide a light emitting diode driving device capable of obtaining an input current waveform proportional to an input voltage waveform without fear of an overcurrent flowing through the switching element.

According to the fifth aspect of the present invention, since the control circuit of the boost chopper is configured to turn off the switching element after a predetermined time has elapsed after the switching element is turned on, light emission with a simplified circuit configuration is achieved. A diode driving device can be provided.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing a light emitting diode driving device according to a first embodiment of the present invention.

FIG. 2 is a waveform chart showing waveforms of voltages and currents of respective units in the first embodiment of the light emitting diode driving device of the present invention.

FIG. 3 is a waveform diagram showing waveforms of an inductor current and a voltage of a switching element near a peak value and near a zero crossing of a power supply voltage in the first embodiment of the light emitting diode driving device of the present invention.

FIG. 4 is a circuit diagram showing a second embodiment of a light emitting diode driving device according to the present invention.

FIG. 5 is a circuit diagram showing a first example of a conventional light emitting diode driving device.

FIG. 6 is a circuit diagram showing a second example of a conventional light emitting diode driving device.

FIG. 7 is a circuit diagram showing a third example of a conventional light emitting diode driving device.

FIG. 8 is a circuit diagram showing a fourth example of a conventional light emitting diode driving device.

FIG. 9 is a waveform diagram showing waveforms of a power supply voltage and an input current in a first example of a conventional light emitting diode driving device.

FIG. 10 is a waveform diagram showing the waveforms of a power supply voltage and an input current in a second example of the conventional light emitting diode driving device.

FIG. 11 is a waveform diagram showing the waveforms of a power supply voltage and an input current in a fourth example of the conventional light emitting diode driving device.

[Explanation of symbols]

 AS: Low frequency AC power supply HF: High frequency filter RDC: Rectified DC power supply BUT: Boost chopper L: Inductor Q: Switching element D: Diode CC: Control circuit DC: Drive signal generation circuit BM: Bistable multivibrator CP: Comparison circuit M: Multiplier LED: Light emitting diode LFC: Light emitting diode current feedback circuit LD: Light emitting diode current detector EA: Error amplifier E: Reference potential source ICC: Integrating circuit SD: Switching current detecting circuit VD: Power supply voltage detecting circuit LD: Inductor Current detection circuit

Claims (5)

[Claims] A rectified DC power supply having an AC input terminal connected to a low-frequency AC power supply; an inductor and a switching element connected in series between the DC output terminals of the rectified DC power supply; and a connection between both ends of the switching element. And a boost chopper having a control circuit for turning on the switching element when the energy stored in the inductor is released and turning off the switching element after a predetermined time; DC of the boost chopper as a load of the boost chopper A light-emitting diode driven by the output; detecting the light-emitting diode current flowing through the light-emitting diode and returning to the control circuit to control the light-emitting diode current to be averaged when viewed in a time region longer than the period of the low-frequency AC. A light emitting diode current feedback circuit for causing the circuit to control the boost chopper. LED driving device, characterized in that. 2. A light emitting diode current feedback circuit comprising: a light emitting diode current detector; an error amplifier for inputting a detection signal output from the light emitting diode current detector to one control input terminal to generate a feedback signal; 3. The light emitting diode driving device according to claim 2, further comprising a reference potential source connected to the other control input terminal, and an integration circuit for forming an integrated feedback signal. 3. The light emitting diode driving device according to claim 2, wherein the reference potential source has a variable reference potential. 4. A switching current detecting circuit according to claim 1, further comprising a switching current detecting circuit for controlling a control circuit so as to turn off the switching element by detecting a current flowing through the switching element. LED driving device. 4. The light emitting diode driving device according to 3. 5. The control circuit according to claim 1, wherein the control circuit is configured to turn off the switching element when a predetermined time elapses after the switching element is turned on.
The light emitting diode driving device according to any one of the above.