KR100936815B1 - Apparatus for driving multi-channel light emitting diodes - Google Patents

Abstract

PURPOSE: An apparatus for driving a multi-channel LED is provided to perform efficiency rising and heating reduction by performing a PWM duty ratio control through a plurality of duty ratio switching circuits. CONSTITUTION: A DC input part(100) confirms a power supplied from a power supply device. A switching/smoothing circuit(110) switches and smoothes an output of the power inputted through the DC input part. A driving control part(140) controls an output voltage of the switching/smoothing circuit. A plurality of LEDs(120) is parallel connected to the switching/smoothing circuit, and forms a plurality of channels. A plurality of duty ratio switching circuits(130) is connected to the channels, and performs a PWM duty ratio control for controlling a flow of a current.

Description

Apparatus for driving multi-channel Light Emitting Diodes

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-output LED driving circuit, and more particularly, to a multi-channel LED driving apparatus that simplifies a constant current circuit and replaces each constant current circuit with one power supply.

Recently, light emitting diodes, or LEDs, have been used as main light sources for mobile devices such as mobile phones. LED is used as the main light source of mobile devices such as cell phones, digital cameras, PDAs (Personal Digital Assistants), and depending on the color of the keypad of the mobile device, R (Red), G (Green, Green), B (Blue, Blue) The white LED using the color of) is used as a back light source of a mobile display, and the demand for this is exploding. In addition, recently, as a back light source of an LCD panel, a plurality of LEDs are connected in series or in place of a commonly used cold cathode fluorescent lamp (CCFL) and an external electrode fluorescent lamp (EEFL). Research and development to use LED arrays connected in series and parallel are in full swing.

In order to realize special lighting, landscape lighting, general lighting, etc. by using LED, in order to make the light emitted from LED uniform and to control color temperature and color brightness, the current flowing through the LED must be You have to control it. In addition, in order to control the constant current, it is preferable to control the control by the PWM method. As such, a circuit for driving the LED by controlling the current so that a constant current flows through the PWM method is called an LED driving circuit.

The LED driving circuit using a conventional switching method includes an input DC power supply, a switching converter, an LED array, and the like. The input DC power supplies the operating power of the LED driving circuit with a DC voltage. LED arrays correspond to multiple rows of LEDs connected in series. The current flowing through the LED array is the forward current (If). The switching converter controls the forward current If. The switching converter may be implemented as a conventional non-isolated step-down converter or step-up converter, but an isolated converter as well as other types of non-cut converters may be used.

However, in order to drive LEDs, constant current driving is required, and when driving multi-output LEDs, many constant current circuits and dimming circuits are required, and different driver selection is required depending on the number and channel of driving LEDs. This increases the complexity of the drive circuit design and increases the cost of the circuit design.

The technical problem to be solved by the present invention relates to a multi-channel LED driving device that can efficiently drive a multi-channel LED without having a constant current circuit for each channel.

In order to achieve the above object, the multi-channel LED driving apparatus according to the present invention includes a DC input unit for confirming the abnormality of the power supplied from the outside; A switching / smoothing circuit for switching and smoothing the output of the power inputted through the DC input unit; A driving controller which controls a set output voltage to be output from the switching / smoothing circuit; Light emitting diodes connected in parallel with the switching / smoothing circuit to form a plurality of channels; And duty ratio switching circuits connected to each of the plurality of channels and configured to control a pulse width modulation (PWM) duty ratio for adjusting a flow of current, wherein the driving controller is configured to flow in each of the plurality of channels. The current is detected and the switching of the duty ratio switching circuits is controlled to have the same brightness for each of the plurality of channels according to the detected result.

According to the present invention, it is possible to effectively control the LED irrespective of the number of LEDs or channels in the LED array, does not need a constant current circuit corresponding to each channel, can reduce heat generation and increase efficiency by PWM Dimming, driving The design cost of the circuit can be reduced and the performance can be improved.

Hereinafter, a multi-channel LED driving apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of an embodiment for explaining a multi-channel LED driving apparatus according to the present invention, and includes a DC input unit 100, a switching / smoothing circuit 110, light emitting diodes 120, and duty ratio switching circuits. 130 and the drive control unit 140.

When the DC input unit 100 receives power from the power supply device, the DC input unit 100 checks whether there is an abnormality of the supplied power, and outputs the confirmation result to the driving controller 140. The driving control unit 140 receives the confirmation result of the DC input unit 100 and finally determines whether there is an abnormality in the input power. On the other hand, the DC input unit 100 outputs the power supplied from the power supply to the switching / smoothing circuit 110.

The switching / smoothing circuit 110 switches and smooths the output of the power source input through the DC input unit 100 and outputs a smoothed voltage. The switching / smoothing circuit 110 switches and smoothes the output of the power in response to the pulse width modulation (PWM) duty ratio control signal of the driving controller 140.

The light emitting diodes 120 are connected in parallel with the switching / smoothing circuit 110 to form a plurality of channels CH ₁ to CHn.

The duty ratio switching circuits 130 are connected in series with the light emitting diodes 12 of the plurality of channels, respectively, and are responsible for PWM (Pulse Width Modulation) duty ratio control for adjusting the flow of current. The duty ratio switching circuits 130 are each composed of a field effect transistor.

The driving controller 140 outputs a pulse width modulation (PWM) duty ratio control signal to the switching / smoothing circuit 110 so that the set output voltage is output from the switching / smoothing circuit 110.

In order to set the output voltage, the driving controller 140 detects an output voltage such that a current flowing in each of the plurality of channels CH ₁ to CHn is equal to a reference current, and outputs a maximum voltage among the detected output voltages. Set to.

2 is a flowchart illustrating a process of setting an output voltage.

First, a reference current is set (step 200). The reference current corresponds to a current value that has a brightness that is a reference for the light emitting diodes in each channel. At this time, the reference current is determined within the maximum current range to prevent the light emitting diodes from being damaged due to overcurrent.

After operation 200, an arbitrary channel is selected (operation 202). As shown in FIG. 1, one of the plurality of channels CH ₁ to CHn is selected.

After step 202, the pulse width modulation (PWM) duty ratio of the selected channel is set to 100 [%] (step 204). The driving controller 140 sets the duty ratio for each of the plurality of channels to 100 [%] to set the output voltage.

After step 204, the output voltage is applied while adjusting the magnitude of the output voltage (step 206).

After step 206, it is checked whether the current of the selected channel whose output voltage is adjusted is equal to the reference current set in step 200 (step 208). The current of the selected channel is compared with the set reference current until its magnitude is the same.

If the current of the selected channel is equal to the magnitude of the set reference current, the output voltage of the selected channel at that time is stored (step 210).

After operation 210, a non-selected channel is selected, and the above-described process is repeated. It is determined whether output voltages for all channels have been detected (step 212).

If the output voltages for all the channel channels are detected, a voltage having a maximum value among the detected output voltages of each channel is detected (step 214).

After operation 214, the detected maximum voltage is set as an output voltage (operation 216).

Meanwhile, the driving controller 140 controls the switching of the duty ratio switching circuits 130 to have the same brightness for each of the plurality of channels. To this end, the driving controller 120 compares the current flowing in the reference channel with the magnitude of the current flowing in the channel selected by the duty ratio switching circuit according to the set output voltage, and performs a PWM (Pulse Width Modulation) duty of the selected channel. Determine the rain.

3 is a flowchart illustrating a process of determining a pulse width modulation (PWM) duty ratio of each channel.

A reference channel is set (step 300). Set the channel that outputs the set output voltage, that is, the maximum voltage, as the reference channel. That is, when setting the output voltage, the channel that outputs the maximum voltage among the output voltages such that the current flowing in each of the plurality of channels becomes equal to the reference current is set as the reference channel.

After operation 300, an arbitrary channel is selected (operation 302).

After operation 302, a current difference between the current of the reference channel and the selected channel is detected (operation 304). For example, if the PWM duty ratio of the reference channel according to the set output voltage is 90 [%] and the resulting current is 100 [mA], if the current of the selected channel is 110 [mA], the current difference is 10 [mA]. Corresponds to

After step 304, a PWM duty ratio corresponding to the detected current difference is detected (step 306). For example, in the above-described step 304, if the current difference is detected as 10 [mA], the PWM duty ratio 81 {%] of the selected channel is detected corresponding to the PWM duty ratio 90 [%] of the reference channel.

After step 306, the unselected channel is selected, and the above-described process is repeated. If the PWM duty ratio for all channels is detected, the process ends (step 308).

Thereafter, the driving controller 140 controls the switching of the duty ratio switching circuits 130 to have the same brightness for each of the plurality of channels according to the determined PWM duty ratio for each of the plurality of channels CH ₁ to CHn.

Such a multi-channel LED driving apparatus of the present invention has been described with reference to the embodiment shown in the drawings for clarity, but this is only an example, and those skilled in the art have various modifications and equivalents therefrom. It will be appreciated that examples are possible. Therefore, the true technical protection scope of the present invention will be defined by the appended claims.

1 is a block diagram of an embodiment for explaining a multi-channel LED driving apparatus according to the present invention.

2 is a flowchart illustrating a process of setting an output voltage.

3 is a flowchart illustrating a process of determining the PWM duty ratio of each channel.

Claims (6)

DC input unit for checking the abnormality of the power supplied from the outside; A switching / smoothing circuit for switching and smoothing the output of the power inputted through the DC input unit; A driving controller which controls a set output voltage to be output from the switching / smoothing circuit; Light emitting diodes connected in parallel with the switching / smoothing circuit to form a plurality of channels; And Connected to the plurality of channels, and including duty ratio switching circuits for controlling a pulse width modulation (PWM) duty ratio for adjusting the flow of current; The driving controller detects a current flowing in each of the plurality of channels, and controls the switching of the duty ratio switching circuits to have the same brightness for each of the plurality of channels according to the detected result. Drive system. The method of claim 1, wherein the driving control unit And detecting an output voltage such that a current flowing through each of the plurality of channels is equal to a reference current, and setting a maximum voltage among the detected output voltages as the output voltage. The method of claim 2, wherein the drive control unit In order to set the output voltage, the multi-channel light emitting diode driving apparatus for setting the PWM duty ratio for each of the plurality of channels to 100 [%]. The method of claim 1, wherein the driving control unit According to the set output voltage, multi-channel emission characterized in that the PWM duty ratio of the selected channel is determined by comparing the current flowing in the reference channel and the current flowing in the channel selected by the duty ratio switching circuit. Diode drive. The method of claim 4, wherein When setting the output voltage, the multi-channel light emitting diode driving apparatus, characterized in that for setting the channel that outputs the maximum voltage of the output voltage to make the current flowing in each of the plurality of channels equal to the reference current . The method of claim 1, wherein the duty ratio switching circuit A multi-channel light emitting diode driving device comprising a field effect transistor.

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