KR100957719B1 - LED Lamp and method of controling the LED lamp - Google Patents

Abstract

The present invention relates to an LED lighting device comprising a plurality of LEDs and a control method thereof. The LED lighting device includes a plurality of LED segments, a variable voltage control unit providing a driving voltage to the LED segments, a plurality of drivers providing an output current to the LED segments, and measuring driving voltages for each of the LED segments. And a voltage measurer configured to measure an output current of each of the LED segments, a data store, and a controller configured to store and manage information about the LED and the LED segments. The controller generates the PWM control signal and the PWM control signal of the output current of the driving voltage for the LED segments to provide a driving voltage and output current using a pulse width modulation scheme to the LEDs of the LED segments. Provides voltage controller and drivers. In addition, the controller is characterized by providing a driving voltage and output current sequentially to a plurality of LED segments using a time division multiplexing scheme.

LED lighting, PWM control, TDM, drive voltage

Description

LED lighting device and its control method {LED Lamp and method of controling the LED lamp}

The present invention relates to an LED lighting device and a control method thereof, and more specifically, to optimize LEDs having different types of driving voltages (Vf) by using a pulse width modulation (PWM) method and a time division multiplexing (TDM) method. It relates to a LED lighting device to drive and a control method thereof.

Light emitting diodes (LEDs) are the next most popular lighting devices. Each LED has its own forward voltage (Vf) value. If the driving voltage exceeds Vf or the allowable current (Ic) exceeds the limit, the LED is destroyed. You will not be able to act as. Therefore, the LED constituting the LED lighting device must always be provided with a rated voltage and current.

On the other hand, even when a plurality of LEDs are produced in a single wafer by the same process, they have different kinds of forward voltages (Vf) due to manufacturing process reasons. As described above, when LEDs having various Vf characteristics are used simultaneously in a single driving circuit, there is a problem in that a mismatch between current and voltage occurs for each LED. Therefore, the greater the Vf mismatch of the LEDs constituting the LED lighting device and the greater the number of LEDs, the more power is wasted and the power efficiency is reduced.

In order to solve this problem, LED lighting fixtures are currently using only LEDs having a single Vf. However, for this reason, LED lighting fixtures composed of a plurality of LEDs have a problem that can be quite expensive.

An object of the present invention for solving the above problems is to provide an LED lighting device that can automatically recognize the parameters for LEDs having different driving voltage (Vf) to optimize the LED driving efficiency.

Another object of the present invention is to provide a control method of an LED lighting apparatus, which segments LEDs and sequentially controls a plurality of LED segments according to PWM control signals generated by using time division multiplexing (TDM).

LED lighting device according to a first aspect of the present invention for achieving the above technical problem,

An LED segment comprising one or more LEDs connected to each other; A data storage unit for storing information about the LED segment and information about the LEDs constituting the LED segment; A variable voltage controller configured to generate a driving voltage for the LED segment using power applied from the outside and provide the driving voltage to the LED segment; A driver for generating an output current of the LED segment and providing the output current to the LED segment; A voltage measuring unit measuring a voltage applied to the LED segment; A current measuring unit measuring an output current of the driver; By using the voltage and current measured by the voltage measuring unit and the current measuring unit, information of the data storage unit, generates a PWM control signal of the driving voltage for the LED segment to provide to the variable voltage controller, the LED segment A control unit for generating a PWM control signal of the output current for the driver and providing the PWM control signal; Equipped,

The variable voltage controller generates a driving voltage of the LED segment according to the PWM control signal from the controller, and the driver generates an output current of the LED segment according to the PWM control signal from the controller.

LED lighting device according to a second aspect of the present invention,

A plurality of LED segments in which one or more LEDs are connected to one another; A data storage unit for storing information about the LED segments and information about the LEDs constituting the LED segments; A variable voltage controller configured to generate driving voltages for the LED segments using power applied from the outside and provide the driving voltages to the LED segments; A plurality of drivers connected to an output terminal of each LED segment and generating and providing an output current for the connected LED segment; A plurality of voltage measuring units measuring a driving voltage applied to each LED segment; A plurality of current measuring units connected to output terminals of each driver and measuring output currents of the connected drivers; By using the voltage and current measured by the voltage measuring unit and the current measuring unit, information of the data storage unit, generates a PWM control signal of the driving voltage for the LED segments to provide to the variable voltage controller, the LED A controller for generating a PWM control signal of the output current for the segments and providing the same to the driver; Equipped,

The controller generates a PWM control signal of the driving voltage for the LED segments and a PWM control signal of the output current, and the variable voltage controller generates a driving voltage for each of the LED segments according to the PWM control signal from the controller. The driver generates an output current for each of the LED segments in accordance with a PWM control signal from the controller.

The data storage unit of the LED lighting apparatus according to the second feature described above includes a first data storage unit and a second data storage unit, wherein the first data storage unit stores parameter information for each LED, and stores the second data. The unit stores parameter information for each LED segment.

The second data storage unit includes driving voltage (Vf), output current (Ic), impedance (Z) and sampling time information (T) according to the TDM scheme for each LED segment,

The parameter information for the LED stored in the first data storage unit preferably includes a driving voltage Vf and an output current Ic.

The control unit of the LED lighting apparatus according to the above-described second feature generates a PWM control signal and a PWM control signal of an output current of a driving voltage for the plurality of LED segments according to a time division multiplexing scheme. The variable voltage controller sequentially generates a driving voltage for each of the LED segments according to the PWM control signal of the controller, sequentially provides the generated driving voltage to the corresponding LED segment, and the driver controls the PWM control signal of the controller. It is desirable to generate an output voltage for the LED segment.

A control method of an LED lighting apparatus according to a second aspect of the present invention, a plurality of LED segments, a variable voltage control unit for providing a driving voltage to the LED segment, a plurality of drivers for providing an output current to the LED segments And relates to a control method of the LED lighting device comprising a control unit for controlling the overall operation,

(a) storing information about LEDs constituting the LED segments in a first data storage in advance; (b) detecting and storing driving voltage, output current, impedance, and sampling time information for each LED segment in a second data storage; (c) generating a PWM control signal of a driving voltage for each LED segment according to a TDM scheme using information stored in the second data storage unit, and providing the generated PWM control signal to a variable voltage controller; (d) generating a PWM control signal of an output current for each LED segment according to a TDM scheme using the information stored in the second data storage unit, and providing the generated PWM control signal to drivers; And control the plurality of LED segments according to a time division multiplexing scheme.

The step (b) of the control method according to the above-described third feature may include: (b1) measuring driving voltages for each LED segment; (b2) measuring the output current for each LED segment; (b3) detecting impedance using the measured driving voltage and output current for each LED segment; (b4) detecting sampling time information according to the TDM scheme by using impedances for the respective LED segments; (b5) storing the measured driving voltage and output current, and the impedance and sampling time information in a second data storage unit; and (b6) calibrating a drive voltage, an output current, and an impedance for each LED segment stored in the second data storage.

The LED lighting apparatus according to the present invention having the above-described configuration automatically recognizes the driving voltage, which is the forward voltage Vf, for each LED constituting the LED lighting apparatus to have optimized parameters, thereby providing various types of driving voltages. LEDs can be optimized and efficiently driven.

In addition, the LED lighting apparatus according to the present invention includes a control unit composed of a microcomputer, a microprocessor, and the like, and the control unit sequentially drives each LED segment according to the TDM method using optimized parameter values, It provides the drive voltage and output current within the appropriate range corresponding to the LED segment. As a result, LEDs having various types of driving voltages can be driven in segments.

In addition, the LED lighting apparatus according to the present invention dualizes a driver for adjusting the output current and a variable voltage controller for adjusting the driving voltage for each LED segment by using the parameters for each of the LED segments initially formed, and for each LED. Segments are sequentially controlled in a time division multiplexing (TDM) manner. As a result, LEDs with various drive voltages and output currents can be optimized in large quantities.

Hereinafter, an LED driving apparatus according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing an overall configuration of an LED driving apparatus according to a preferred embodiment of the present invention. Referring to Figure 1 will be described in detail the configuration and operation of the LED driving apparatus according to the preferred embodiment. Referring to FIG. 1, the LED lighting device 10 according to the present invention includes a plurality of LED segments 100, a variable voltage controller 110, a driver 120 connected to an output terminal of each LED segment, and each driver. A current measuring unit 130 connected to an output terminal, a voltage measuring unit 140 connected to each LED segment, a controller 150 and a data storage unit 160 are provided.

Each of the LED segments 100 is formed by connecting one or more LEDs in series.

The data storage unit 160 includes a first data storage unit 162 and a second data storage unit 164. The first data storage unit 162 stores and manages parameter information provided by a manufacturer for LEDs constituting the LED lighting device, and stores the parameter information as a driving voltage Vf and an output current for each LED. (Ic) and the like.

The second data storage unit 164 is formed of an EEPROM capable of erasing and recording data, and information on each LED segment is sequentially stored, and the information on each LED segment is detected by the controller. It includes the operating voltage (X), output current (Y), impedance (Z), and TDM sampling time information (T) for the corresponding LED segment, and is continuously updated by the controller. 3 is a diagram exemplarily illustrating information stored in a second data storage unit according to an exemplary embodiment of the present invention. The second data storage unit may be used as data for making optimization parameters in the future, and the information stored in the second data storage unit may be checked in a GUI environment by a computer simulation program. As shown in FIG. 3, the second data storage unit of the LED lighting apparatus according to the present invention comprises unit information for a single LED segment by configuring X, Y, and Z information about a sampling time and T, which is sampling time information. It makes it easy to see the parameters of each LED segment.

The variable voltage controller 100 receives power from an external source, receives a PWM control signal for a driving voltage to be sequentially provided to each LED segment according to a TDM scheme, and according to the received PWM control signal. A driving voltage is generated from the power supply, and the generated driving voltages are sequentially provided to respective LED segments. 4A is a timing diagram exemplarily illustrating a PWM control signal provided from the controller to the variable voltage controller. As shown in FIG. 4A, the PWM control signal of the driving voltage for each LED segment is provided to the variable voltage controller according to the TDM scheme.

The variable voltage controller 100 of the LED lighting apparatus according to a preferred embodiment of the present invention receives an AC power from the outside and converts the DC power into a direct current, and modulates the converted DC voltage according to the PWM control signal provided from the controller. It will serve as an LED segment. In this case, the AC power applied by the variable voltage controller 100 may be 110VAC, 220VAC, 277VAC, 347VAC, or the like.

The driver 120 is connected to an output terminal of each LED segment, and controls the output current of each LED segment according to the PWM control signal for the output current from the control unit, thereby driving the LEDs of the LED segment. 4B is a timing diagram exemplarily illustrating a PWM control signal provided from the controller to the driver. As shown in (b) of FIG. 4, the PWM control signal of the output current for each LED segment is provided to each driver according to the TDM scheme.

The current measuring unit 130 is connected to the output terminal of each driver in series to measure the output current of the driver to provide to the controller.

The voltage measuring unit 140 is connected to the input terminal and the output terminal of each LED segment in parallel to measure the driving voltage applied to the corresponding LED segment to provide to the controller.

The controller 150 measures parameter information for each LED stored in the first data storage 162, parameter information for each LED segment stored in the second data storage 164, and measures the current by the current measurement unit. Drive currents (X), output currents (Y) to be provided to each LED segment, using the output currents for each of the LED segments, and the driving voltages applied to each LED segment measured by the voltage measuring unit, Sampling time information T according to the impedance Z and the TDM method is detected. The control unit stores the detected information in the second data storage unit and simultaneously generates a PWM control signal for a driving voltage and an output current for controlling each LED segment and provides them to the variable voltage controller and the driver. Each LED segment will be driven.

2 is a flowchart sequentially illustrating the operation of the controller 150 of the LED lighting apparatus according to the preferred embodiment of the present invention. Hereinafter, the operation of the controller 150 according to the present invention will be described in detail with reference to FIG. 2.

First, an initialization operation is performed as power is applied to the LED lighting device (step 200). The initialization operation in step 200 includes reading parameter information on the LEDs from the first data storage unit, selecting a frequency for PWM control, and selecting a measurement range of each current measuring unit and the voltage measuring unit.

Next, it is checked whether it is the first boot (step 210), and if it is the first boot, an initial calibration operation is performed (step 212). The initial calibration operation in step 212 applies a driving voltage Vf for each LED segment, measures the output current Ic for each LED segment through the current measuring unit, and uses the driving voltage and the output current to impedance (Z), and after detecting sampling time information (T) according to the TDM method using the impedance, the detected driving voltage (Vf), output current (Ic), impedance (Z) for each LED segment. And the sampling time information T is stored in the second data storage unit.

If the first booting is not performed in step 210, PWM control of the driving voltage of each LED segment is performed using the driving voltage Vf and the sampling time information T for each LED segment among the information stored in the second data storage. A signal is generated and the generated PWM control signal is provided to the variable voltage controller (step 220).

Next, the voltage applied to each LED segment is measured through the voltage measuring unit of each LED segment, and the driving voltage Vf is compared with the measured voltage to determine whether it is the same (step 230).

If the driving voltage and the measured voltage are not the same in step 230, adjust the frequency of the PWM control signal of the driving voltage, redetect the driving voltage, output current and impedance according to the adjusted frequency to the second data Store to storage (step 232).

If the driving voltage and the measured voltage are the same in step 230, the margin range for the driving voltages Vf and Vf of the LED read out from the first data storage unit is compared with the measured driving voltage. Then, it is determined whether the measured driving voltage is within a margin range of the driving voltage Vf of the read LED (step 240). If the measured driving voltage is out of the margin range of Vf of the read LED in step 240, the driving voltage is calibrated (step 270) and stored in the second data storage unit.

Next, the margin ranges for Ic and Ic of the LED read out from the first data storage unit are compared with the measured output current to determine whether the measured output current is within the margin range of the read Ic. (Step 250). If the measured output current is out of the margin range of Ic of the read LED in step 250, the output current is calibrated (step 270) and stored in the second data storage.

Next, the rated impedance of the LED read out from the first data storage unit is compared with the detected impedance to determine whether the detected impedance is within the range of the read rated impedance (step 260). If the detected impedance in step 260 is out of the range of the read rated impedance, the impedance is calibrated (step 270) and stored in the second data storage.

Next, generate a PWM control signal for the output current of each LED segment, and provide the PWM control signal to the driver (step 290). 4B is a timing diagram exemplarily illustrating a PWM control signal for an output current of each LED segment provided to each driver.

Next, the output current for each LED segment is measured through the current measuring unit, and the measured output current is compared with the Ic stored in the second data storage unit to determine whether it is the same (step 292). If the measured output current and Ic stored in the second data storage unit are the same in step 292, the operation ends. Otherwise, the process returns to step 220 and repeatedly performed.

Although the present invention has been described above with reference to preferred embodiments thereof, this is merely an example and is not intended to limit the present invention, and those skilled in the art do not depart from the essential characteristics of the present invention. It will be appreciated that various modifications and applications which are not illustrated above in the scope are possible. And differences relating to such modifications and applications should be construed as being included in the scope of the invention as defined in the appended claims.

The LED driving device according to the present invention can be widely used as a driving power source for an LED lighting device composed of a plurality of LEDs.

1 is a block diagram showing an overall configuration of an LED driving apparatus according to a preferred embodiment of the present invention.

2 is a flowchart sequentially illustrating the operation of the controller 150 of the LED lighting apparatus according to the preferred embodiment of the present invention.

3 is a diagram exemplarily illustrating information stored in a second data storage unit according to an exemplary embodiment of the present invention.

4A is a timing diagram exemplarily illustrating a PWM control signal provided to the variable voltage controller from a controller of an LED driving apparatus according to an exemplary embodiment of the present invention, and FIG. An example timing diagram illustrating a PWM control signal for the output current of each LED segment provided by.

<Explanation of symbols for the main parts of the drawings>

10: LED lighting device

110: LED Segment

110: variable voltage control unit

120: driver

130: current measuring unit

140: voltage measuring unit

150: control unit

160: data storage unit

162: first data storage

164: second data storage

Claims (10)

An LED segment comprising one or more LEDs connected to each other; A data storage unit for storing information about the LED segment and information about the LEDs constituting the LED segment; A variable voltage controller configured to generate a driving voltage for the LED segment using power applied from the outside and provide the driving voltage to the LED segment; A driver for generating an output current of the LED segment and providing the output current to the LED segment; A voltage measuring unit measuring a voltage applied to the LED segment; A current measuring unit measuring an output current of the driver; By using the voltage and current measured by the voltage measuring unit and the current measuring unit, information of the data storage unit, generates a PWM control signal of the driving voltage for the LED segment to provide to the variable voltage controller, the LED segment A controller for generating a PWM control signal of an output current for the driver and providing the PWM control signal to the driver;  And the variable voltage controller generates a driving voltage of the LED segment according to the PWM control signal from the controller, and the driver generates an output current of the LED segment according to the PWM control signal from the controller. LED lighting device. A plurality of LED segments in which one or more LEDs are connected to one another; A data storage unit for storing information about the LED segments and information about the LEDs constituting the LED segments; A variable voltage controller configured to generate driving voltages for the LED segments using power applied from the outside and provide the driving voltages to the LED segments; A plurality of drivers connected to an output terminal of each LED segment and generating and providing an output current for the connected LED segment; A plurality of voltage measuring units measuring a driving voltage applied to each LED segment; A plurality of current measuring units connected to output terminals of each driver and measuring output currents of the connected drivers; By using the voltage and current measured by the voltage measuring unit and the current measuring unit, information of the data storage unit, generates a PWM control signal of the driving voltage for the LED segments to provide to the variable voltage controller, the LED A controller for generating a PWM control signal of the output current for the segments and providing the same to the driver;  And the controller generates a PWM control signal of the driving voltage and an output current PWM control signal for the LED segments, and the variable voltage controller drives the respective LED segments according to the PWM control signal from the controller. Generating a voltage, wherein the driver generates an output current for each of the LED segments in accordance with a PWM control signal from the controller. The data storage unit of claim 2, wherein the data storage unit comprises a first data storage unit and a second data storage unit, the first data storage unit stores parameter information for each LED, and the second data storage unit is configured to each LED segment. LED lighting device, characterized in that for storing parameter information. The method of claim 3, wherein the second data storage unit includes driving voltage Vf, output current Ic, impedance Z, and sampling time information T according to a TDM scheme for each LED segment. LED lighting device. 4. The LED lighting apparatus of claim 3, wherein the parameter information for the LED stored in the first data storage unit includes a driving voltage (Vf) and an output current (Ic). The method of claim 2, wherein the controller is further configured to generate a PWM control signal of a driving voltage and an output current of a PWM control signal for the plurality of LED segments according to a time division multiplexing scheme. The variable voltage controller sequentially generates driving voltages for each of the LED segments according to the PWM control signal of the controller, and sequentially provides the generated driving voltages to the corresponding LED segments. And the driver generates an output voltage for the LED segment according to the PWM control signal of the controller. In the control method of the LED lighting device comprising a plurality of LED segments, a variable voltage control unit for providing a driving voltage to the LED segment, a plurality of drivers for providing an output current to the LED segments, a control unit for controlling the overall operation, The control method, (a) storing information about LEDs constituting the LED segments in a first data storage in advance; (b) detecting and storing driving voltage, output current, impedance, and sampling time information for each LED segment in a second data storage; (c) generating a PWM control signal of a driving voltage for each LED segment according to a TDM scheme using information stored in the second data storage unit, and providing the generated PWM control signal to a variable voltage controller; (d) generating a PWM control signal of an output current for each LED segment according to a TDM scheme using information stored in the second data storage unit, and providing the generated PWM control signal to drivers; The control method of the LED lighting device, characterized in that for controlling the plurality of LED segments in accordance with the TDM scheme. The method of claim 7, wherein step (b), (b1) measuring the driving voltage for each LED segment; (b2) measuring the output current for each LED segment; (b3) detecting impedance using the measured driving voltage and output current for each LED segment; (b4) detecting sampling time information according to the TDM scheme by using impedances for the respective LED segments; (b5) storing the measured driving voltage and output current, and the impedance and sampling time information in a second data storage unit; Control method of the LED lighting device characterized in that it comprises a. The method of claim 8, wherein step (b) further comprises the step of (b6) calibrating the driving voltage, output current and impedance for each LED segment stored in the second data storage. Control method. 10. The method of claim 9, wherein step (b6) is repeated until the measured output current falls within a range of rated current stored in the first data storage.

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