KR101549491B1 - AC LED driving circuit with current source of cascode type - Google Patents

Abstract

In the present invention, in the AC LED driving circuit having the cascode structure, that is, the switching circuit portion of the cascode structure, the headroom voltage value of each switching circuit portion is kept constant, and the characteristics of the clamping element, The present invention relates to an AC LED driver circuit having a current source of a cascode structure that allows all switching circuits to always operate under the same conditions regardless of external temperature, An LED lighting unit including an n-th LED located at a longest distance from the power supply unit starting from a first LED located at a distance from the power supply unit; A plurality of switching circuit units forming a channel, And a voltage headroom control unit connected to the corresponding LED-to-LED connection line, wherein the voltage headroom control unit is separately installed in a connection line between the corresponding LEDs of the switching circuit units and the LED illumination unit, A plurality of clamp elements connected to the connection lines between the clamp elements and the switching circuit sections and receiving a node value for each of the clamp elements and receiving a bias value of a gate or a base of the clamp element, And a bias adjusting unit for adjusting a value of the bias voltage.

Description

[0001] AC LED driving circuit with current source of cascode type [

The present invention relates to an LED driving circuit, and more particularly, to an AC LED driving circuit having a current source of a cascode structure, that is, a switching circuit portion of a cascode structure, a headroom voltage value of each switching circuit portion is maintained constant, The present invention relates to an AC LED driver circuit having a current source of a cascode structure that allows all switching circuits to always operate under the same condition regardless of the characteristics of the device, the current value per channel, and the external temperature.

The AC LED driving circuit proposed in the method of driving the LED under the AC (AC) power supply has advantages such as simple manufacturing process, low defect rate and long life time compared with the SMPS (Switched mode power supply) method.

The basic principle of such an AC LED driving circuit is to sequentially control the current sources.

Referring to FIG. 1, FIG. 1 illustrates a conventional AC LED driving circuit. As shown in FIG. 1, the AC LED driving circuit determines the performance of the current source expressed by the LEDs ILED1 through ILEDn. In other words, the control performance of the AC LED driver circuit depends on the performance of the current sources, and therefore, the improvement of the performance of the current sources is directly related to the improvement of the control performance of the AC LED driver circuit.

For reference, factors that determine the basic performance of a common current source include the accuracy of the current value, the impedance at both ends, the time for normal operation after the start of operation, the temperature and voltage, and the degree of maintaining the same value under various external conditions. There are various structures for satisfying these factors. One of widely used methods is a cascode structure.

2 shows a basic cascode structure. Referring to FIG. 2, the cascode structure basically includes a current source 10 for setting a current, a clamp cell 20 biased in a common gate (or common base) And a power supply 30 connected to the gate (or base) of the power supply 20. Here, if the clamp cell 20 is formed of a high voltage transistor, a breakdown voltage necessary for the AC LED driving circuit can be realized, and the AC LED driving circuit can be constructed using the breakdown voltage.

3 is a diagram showing an example of an AC LED driving circuit using a cascode structure.

Referring to this, a current source for each channel is configured using M1 to M4, SA1 to SA4, and Rs, and UHV1 to UHV4 serve as clamps for the respective channels. The gate of the FET that constitutes the clamp receives the voltage from VCC2 and forms a bias.

However, the AC LED driving circuit having the above-described structure may cause the following problems.

That is, since VCC2 is fixed, the voltage of the node from N1 to N4 is determined by the threshold voltage of each of current values I1 to I4 and UHV1 to UHV4 flowing in UHV1 to UHV4.

Accordingly, when the difference between the values of I1 to I4 is large, a voltage value deviation of the nodes N1 to N4 may occur, and a voltage value deviation of the nodes N1 to N4 may occur with respect to an external temperature change. In addition, voltage fluctuations of nodes N1 to N4 may occur due to process variations of high voltage transistors for clamps UVH1 to UVH4. When UVH1 to UVH4 are implemented by external transistors, N1 to N4 A voltage value deviation of the node may occur.

These problems can directly affect the uniformity, reliability, and service life of AC LED driver circuits and products including them.

Korean Registered Patent No. 1040135 (issued on June 13, 2011), "LED Lighting Device Driven by AC Power Source" Korean Registered Patent No. 0971789 (issued on July 21, 2010), "AC LED Driving Circuit"

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above problems, and it is an object of the present invention to provide a current source of a cascode structure, that is, an AC LED driving circuit having a switching circuit portion of a cascode structure, And a current source of a cascode structure that allows all the switching circuits to always operate under the same condition regardless of the characteristics of the clamp device, the current value per channel, and the external temperature.

In order to achieve the above object, an AC LED driving circuit having a current source of a cascode structure according to the present invention includes a first LED located at a shortest distance from a connection point with a power supply unit, a plurality of switching circuit units individually connected to output terminals of one or two or more LEDs forming the LED lighting unit to form current supply channels for the LEDs; And a voltage headroom controller connected to the corresponding LED interconnection line of the switching circuit units to maintain a constant headroom voltage value of the switching circuit units.

The voltage headroom control unit may include a plurality of clamp elements separately mounted on connection lines between the corresponding LEDs of the switching circuit units and the LED illumination unit and biased in a common gate or common base manner, And a bias adjuster connected to an interconnection line for receiving the node value of each clamp device and adjusting a bias value of a gate or a base of the clamp device based on the input node value.

The bias adjusting unit may maintain the voltage value of each of the plurality of clamp devices at a preset voltage or a similar voltage value within an error range of ± 5 to 10% with respect to the preset voltage.

And the preset voltage of the bias adjusting unit is an input voltage to the bias adjusting unit.

The bias adjusting unit controls a headroom voltage value of the switching circuit units on the basis of the operation confirmation signal to which the operation confirmation signal of the switching circuit units is separately inputted.

The bias adjusting unit may include a plurality of first operational amplifiers that individually match the clamping elements to input node values of the clamping elements and a common threshold voltage of a voltage value for switching operations of the switching circuit units, Connected in parallel on the node value input line of the clamping element for the first OP amplifier in a state of being individually matched with the first OP amplifiers and being on / off controlled in accordance with the output value of the corresponding first OP amp And a second OP amplifier connected in parallel with output terminals of the switches and receiving a preset voltage for the bias adjusting unit. Here, the bias adjuster controls on / off operations of the switches based on node values of the clamp elements according to the output value of the first OP amplifier, to which the output values of the first OP amplifiers are separately inputted And may further include a switch control section.

In addition, the LED illumination unit may include a configuration in which a plurality of LEDs form an individual LED illumination, a configuration in which one or more LED lights formed by grouping two or more LEDs are connected, an LED illumination unit formed by one LED, And the switching circuit unit is connected to an output terminal of the final LED of each LED lighting.

The power supply unit may include an AC power supply and a rectifier circuit of the AC power supply.

Further, the AC LED driving circuit having a current source of a cascode structure according to the present invention may further include a switching confirmation unit connected to the switching circuit units to detect whether the corresponding switching circuit unit is operated, and the bias adjustment unit may detect And the headroom voltage value of the switching circuit units is controlled based on the signal. Here, the switching confirmation unit may be a current sensing unit installed at an input terminal or an output terminal of the switching circuit unit to sense an input current or an output current of the switching circuit unit.

According to the present invention, in a current source of a cascode structure, that is, in an AC LED driving circuit having a switching circuit portion of a cascode structure, the headroom voltage value of each switching circuit portion is kept constant so that characteristics of the clamping element, All switching circuits can always be driven under the same conditions regardless of current value, external temperature, and the like.

1 is a view showing a conventional AC LED driving circuit
2 is a diagram showing a basic cascode structure;
3 is a diagram showing an example of an AC LED driving circuit using a cascode structure
4 is a conceptual view of an AC LED driving circuit having a current source of a cascode structure according to an embodiment of the present invention;
5 is a view showing a main part of an AC LED driving circuit having a current source of a cascode structure according to an embodiment of the present invention;
6 is a view showing a main part of an AC LED driving circuit having a current source of a cascode structure according to another embodiment of the present invention
7 is a view showing a main part of an AC LED driving circuit having a current source of a cascode structure according to still another embodiment of the present invention

Hereinafter, an ac LED driver circuit having a current source of a cascode structure according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

4 is a conceptual view of an AC LED driving circuit having a current source of a cascode structure according to an embodiment of the present invention.

1, an AC LED driving circuit 100 (hereinafter abbreviated as "AC LED driving circuit") having a current source of a cascode structure according to an embodiment of the present invention includes a power supply unit 110, an LED illumination unit 120, A plurality of switching circuit units 130, and a voltage headroom controller 140.

The power supply unit 110 supplies power to the AC LED driving circuit. In the present embodiment, the power supply unit 110 includes a rectifier circuit of an AC power source and an AC power source. However, It is not.

The LED lighting unit 120 includes a third LED 120-3 located at the longest distance from the power supply unit 110 starting from the first LED 120-1 located at the shortest distance from the connection point with the power supply unit 110 . The LED illumination unit 120 may be configured such that a plurality of LEDs form an individual LED illumination, a configuration in which one or more LED lights formed by grouping two or more LEDs are connected, an LED illumination formed by one LED, LEDs formed by LEDs are connected to each other, and the switching circuit unit 130 is connected to the output terminal of the final LED of each LED lighting.

In this embodiment, a plurality of LEDs form individual LED lights, and the switching circuit unit 130 is connected to each output terminal of each LED.

 The switching circuit unit 130 is individually connected to the output terminals of one or more LEDs forming the LED illumination unit 120 to form current supply channels for the LEDs. In this embodiment, detailed description and description of the switching circuit unit 130 are omitted. As an example of the switching circuit unit 130, a configuration including a field effect transistor (MOS FET) and an OP amp comparator may be used, Here, the field effect transistor may be configured such that a drain is connected to the LED output terminal of the LED illumination unit 120, a source is connected to the ground resistance, and a gate is connected to the OP amp comparator.

The voltage headroom control unit 140 is connected to the corresponding LED connection lines of the switching circuit units 130 and the LED lighting unit 120 to maintain a constant headroom voltage value of the switching circuit units 130 do.

The headroom controller 140 may include a plurality of clamp devices 141 and a bias adjuster 142.

The plurality of clamp elements 141 are individually provided on the connection lines between the corresponding LEDs of the switching circuit units 130 and the LED illumination unit 120 and are biased in a common gate or common base manner.

The bias adjusting unit 142 is connected to the connection line between the clamping elements 141 and the switching circuit units 130 and receives a node value for each of the clamping elements 141. Based on the input node value, ) Of the gate or base. Here, the bias adjuster 142 may maintain the voltage value of a node for each of the plurality of clamp devices 141 at a preset voltage or a similar voltage value of an error range of ± 5 to 10% with respect to the preset voltage have. Also, the preset voltage of the bias adjusting unit 142 may be an input voltage to the bias adjusting unit 142.

An example of such a bias adjusting unit 142 will be described with reference to FIG.

As shown in the figure, the bias adjusting unit 142 may include a plurality of first OP amplifiers 142a, a plurality of switches 142b, and a second OP amplifier 142c. The bias adjusting unit 142 may further include a switch control unit 142d.

The plurality of first OP amplifiers 142a are individually matched with the clamp devices 141 so that the node values of the clamp devices 141 are input and the voltage values common to the switching circuits 130 The threshold voltages are individually input.

The plurality of switches 142b are connected in parallel on the input line of the node value of the clamp element 141 to the first OP amplifier 142a in a state of individually matching with the first OP amplifiers 142a, And is on / off controlled in accordance with the output value of the amplifier 142a.

The second OP amplifier 142c is connected in parallel with the output terminals of the switches 142b, and a preset voltage for the bias adjuster 142 is input.

The switch control unit 142d switches the switch 142b based on the node value of the clamp elements 141 according to the output value of the first OP amplifier 142a to which the output values of the first OP amplifiers 142a are separately input, Off operation of the microcomputer. For example, the switch control section (142d) is _{V N1> V CHth, V N2} <V CHth, V N3 <V CHth case of the control to be connected to only the SW1, and _{V N1> V CHth, V N2} > V CHth, V N3 In case of <V _CHth , only SW2 is controlled to be connected. In the case of V _N1 > V _CHth , V _N2 > V _CHth and V _N3 > V _CHth , only _{SW 3} is controlled to be connected. Accordingly, the operating condition of the switch 142b necessary for controlling the headroom voltage can be set through the appropriate logic combination of the switch controller 142d.

4, when the Vref1 value is set to a value slightly higher than the minimum or minimum value of the N1 to N3 node voltages required for the operation of the switching circuit units 130 through the AC LED driving circuit 100 shown in FIG. 4, The voltage values of the nodes N1 to N3 converge to the value Vref1 or a value close to the value of Vref1 during operation, so that the switching circuit units 130 can always be driven under the same conditions do.

Next, another embodiment of the AC LED driver circuit according to the present invention will be described with reference to FIGS. 6 and 7. FIG.

First, an AC LED driver circuit according to another embodiment of the present invention will be described with reference to FIG. 6. As compared with the AC LED driver circuit 100 according to FIG. 4 and FIG. 5, The bias adjusting unit 242 will be mainly described. The same parts as those of the AC LED driving circuit 100 according to FIGS. 4 and 5 will be described in detail with the same reference numerals being omitted. I will reveal.

As shown in the figure, the AC LED driving circuit 200 receives the operation confirmation signals of the switching circuit units 130 separately from the bias adjustment unit 242, and the bias adjustment unit 242 performs switching And controls the value of the headroom voltage of the circuit units 130.

That is, the AC LED driving circuit 200 may require an appropriate time for headroom control since each switching circuit 130 has an exclusive operation point with respect to each other. For example, when the first switching circuit 130 operates, the headroom voltage needs to be controlled using only the voltage of the node N1, and the second switching circuit 130 (current source 2) Only the voltage of the node N2 is used and when the third switching circuit 130 is operated, only the voltage of the node N3 is used to control the headroom voltage This can happen if you have to.

At this time, the operation of the switching circuit unit 130 can be checked by detecting a change in the voltage value of a specific part in each circuit constituting the switching circuit unit 130, The bias adjusting unit 242 can select the voltage values of the nodes N1 to N3 using the voltage values S1 to S3 to control the headroom voltage.

Next, an alternating-current LED driving circuit according to another embodiment of the present invention will be described with reference to FIG. 7. As compared with the alternating-current LED driving circuit 100 according to FIG. 4 and FIG. 5, There is a difference in the configuration and operation of the bias adjusting unit 342 according to the switching confirming unit 350 and the switching confirming unit 350 and the bias adjusting unit 342 The same parts as those of the AC LED driver circuit 100 according to FIGS. 4 and 5 are not described in detail, and the same reference numerals are used.

As shown in the figure, the switching confirmation unit 350 is individually connected to the switching circuit units 130 to detect whether the corresponding switching circuit unit 130 is operating. Here, the switching confirmation unit 350 may be a current sensing unit installed at the input or output terminal of the switching circuit unit 130 to sense an input current or an output current of the switching circuit unit 130. In the following description, the switching confirmation unit 350 will be described as an example of a current sensing unit.

The bias adjusting unit 342 controls the headroom voltage value of the switching circuit units 130 based on the sensing signal of the current sensing unit 350.

6, a method of determining whether the switching circuit unit 130 is in operation is performed through a current sensing unit 350 connected in series to the switching circuit unit 130. The current sensing unit 350, which is connected in series to the switching circuit unit 130, Signals S21 to S23 indicating whether or not a current flowing in the current sensing unit 130 is generated are input to the bias adjusting unit 342. The bias adjusting unit 342 receives the signals from the nodes N1 to N3 So that the headroom voltage is controlled.

4 to 7, the AC LED driving circuit having the current source of the cascode structure according to the present invention is characterized in that in the AC LED driving circuit having the switching circuit portion of the cascode structure, By keeping the headroom voltage value of the circuit part constant, all the switching circuit parts are always driven under the same condition regardless of the characteristics of the clamp element, the current value per channel, and the external temperature.

The present invention is not limited to the above-described embodiment, but may be applied to other types of LED driving circuits having a current source of a cascode structure according to the present invention. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

100, 200, 300: AC LED driving circuit 110: Power supply unit
120: LED lighting unit 130: switching circuit
140: Voltage headroom control section 141: Clamp element
142, 242, 342: bias adjuster 142a: first OP amplifier
142b: switch 142c: second OP amp
142d: Switch control section 350: Switching confirmation section

Claims (11)

An LED lighting unit including an n-th LED unit positioned at a longest distance from the power supply unit, starting from a first LED unit located at a shortest distance from a connection point with the power supply unit;
A plurality of switching circuit units individually connected to output terminals of one or two or more LEDs forming the LED illumination unit to form current supply channels for the LEDs;
And a plurality of LEDs connected to corresponding switching LEDs of the switching circuit units and the LED lighting unit to maintain a headroom voltage value of the switching circuit units constant, And a plurality of clamp elements connected to the connection lines between the clamp elements and the switching circuit sections to receive a node value for each of the clamp elements, And a bias adjusting unit for adjusting a bias value of a gate or a base of the clamping element based on the voltage of the current source. delete The method according to claim 1,
Wherein the bias adjusting unit maintains a voltage value of each of the plurality of clamp elements at a preset voltage or a similar voltage value within an error range of ± 5 to 10% with respect to the preset voltage. An AC LED drive circuit having a current source. The method of claim 3,
And the preset voltage of the bias adjusting unit is an input voltage to the bias adjusting unit. The method according to claim 1,
Wherein the bias adjustment unit controls a headroom voltage value of the switching circuit units based on the operation confirmation signal to which the operation confirmation signal of the switching circuit units is separately input and inputted, AC LED drive circuit. The method according to claim 1,
Further comprising a switching confirmation unit connected to the switching circuit units to detect whether the switching circuit unit is operated,
Wherein the bias adjustment unit controls a headroom voltage value of the switching circuit units based on a sensing signal of the switching confirmation unit. The method according to claim 6,
Wherein the switching confirmation unit is a current sensing unit installed at an input or output terminal of the switching circuit unit to sense an input current or an output current of the switching circuit unit. The apparatus of claim 1, wherein the bias adjuster
A plurality of first OP amplifiers individually matched with the clamp elements to input node values of the clamp elements and simultaneously input common threshold voltages of voltage values for switching operations of the switching circuit sections;
A plurality of first and second operational amplifiers connected in parallel on a node value input line of the clamping element to the first operational amplifier in a state of being individually matched with the first operational amplifiers and being controlled on and off according to an output value of the first operational amplifier; switch;
And a second OP amplifier connected in parallel with output terminals of the switches and receiving a preset voltage for the bias adjusting unit. 9. The method of claim 8,
The bias adjuster includes a switch controller for controlling on / off operations of the switches based on a node value of the clamp elements according to an output value of the first OP amplifier input to the first OP amplifiers, Further comprising a current source connected to the power supply line. The method according to claim 1,
The LED illumination unit may be configured in such a manner that a plurality of LEDs form an individual LED illumination, a configuration in which one or more LED lights formed by grouping two or more LEDs are connected, an LED illumination formed by one LED, And the switching circuit unit is connected to an output terminal of a final LED of each LED lighting. The AC LED driving circuit according to claim 1, wherein the switching circuit unit is connected to the output terminal of the LED. The method according to claim 1,
Wherein the power supply unit includes an AC power supply and a rectification circuit of the AC power supply.

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