Patent Grant
9510408
This application claims the priority benefit of Taiwan application serial no. 104129473, filed on Sep. 7, 2015. The entirety of the above-mentioned patent application is hereby incorporated by reference herein and made a part of this specification.
Field of the Invention
The invention is directed to a driving technique of a light emitting diode (LED) and more particularly, to an LED backlight module and driving apparatus.
Description of Related Art
In recent years, with the rapid development of semiconductor technology, portable electronic products and flat panel display products also become popular. Among a variety of types of flat panel displays, a liquid crystal display (LCD) has become a main stream in various display products due to its advantages of low voltage operation, no irradiation, light weight, small volume, etc. Generally, since an LCD panel is not self-luminous, a backlight module has to be disposed under the LCD panel to provide a light source for the LCD panel.
Conventional backlight modules are approximately classified as two types. One is a backlight module composed of cold cathode fluorescent lamps (CCFLs), and the other is a backlight module composed of light-emitting diodes (LEDs). Since the LED backlight module may enhance a color gamut of the LCD, various display panel manufacturers generally use the LED backlight module to replace the CCFL backlight module.
The LED backlight module has a plurality of LED strings arranged in parallel, and each of the LED strings is composed of a plurality of LEDs connected in series. Basically, all LED strings can be operated in a system voltage generated by a boost unit, so as to maintain a current flowing through each LED string at the same constant current.
On the other hand, in some applications, there might be requirements for adjusting brightness because of being cooperated with ambient light or the displayed frames being different. At this current stage, a most commonly used method includes providing a dimming signal, filtering the dimming signal through external capacitors and resistors to generate an analog voltage signal, and then comparing the analog voltage signal with a feedback voltage signal from the LED string to control the system voltage, so as to achieve the purpose of dimming. However, in this method, a driving apparatus equipped with the LED string needs additional pins for connecting the external capacitors. Besides, a frequency of the dimming signal cannot be too low, or the filtered analog voltage signal will become distorted and cannot accurately adjust the brightness of the image frames.
Accordingly, the invention provides a light emitting diode (LED) backlight module and a driving apparatus thereof, where the driving apparatus is capable of converting a pulse width modulation (PWM) based dimming signal into an analog voltage signal without connecting any external capacitor and accurately adjusting brightness of a displayed image frame according to the dimming signal at any frequency.
According to an embodiment of the invention, an LED driving apparatus adapted to drive at least one LED string is provided. The LED driving apparatus includes a sensing resistor, an adjustable voltage-divider circuit, a comparator, a power converter and a control circuit. A first terminal of the sensing resistor is coupled to a cathode of the at least one LED string to generate a feedback voltage, and a second terminal of the sensing resistor is coupled to a ground potential. The adjustable voltage-divider circuit is configured to generate a reference voltage according to a dividing ratio, wherein the dividing ratio of the adjustable voltage-divider circuit is controlled by a first signal set and a second signal set. A first input terminal of the comparator is coupled to the first terminal of the sensing resistor to receive the feedback voltage, a second input terminal of the comparator is coupled to the adjustable voltage-divider circuit to receive the reference voltage, and an output terminal of the comparator is configured to generate a control signal. The power converter is coupled between the output terminal of the comparator and an anode of the at least one LED string and configured to provide a DC voltage to the anode of the at least one LED string according to the control signal. The control circuit is coupled to the adjustable voltage-divider circuit and configured to receive the dimming signal. The control circuit counts a disable period of the dimming signal to generate the first signal set and counts an enable period of the dimming signal to generate the second signal set.
In an embodiment of the invention, the adjustable voltage-divider circuit includes a first controllable resistor and a second controllable resistor. A first terminal of the first controllable resistor is coupled to a power potential, and a second terminal of the first controllable resistor is coupled to a first node. A first terminal of the second controllable resistor is coupled to the first node to generate the reference voltage, and a second terminal of the second controllable resistor is coupled to the ground potential. The first controllable resistor is controlled by the first signal set to adjust a resistance of the first controllable resistor, and the second controllable resistor is controlled by the second signal set to adjust a resistance of the second controllable resistor.
In an embodiment of the invention, an equivalent resistance of the first controllable resistor is positively correlated to a length of the disable period of the dimming signal, and an equivalent resistance of the second controllable resistor is positively correlated to a length of the enable period of the dimming signal.
In an embodiment of the invention, the first controllable resistor includes a plurality of switching resistor modules. The switching resistor modules are sequentially connected in series. A first-stage switching resistor module among the switching resistor modules is coupled to the power potential, a last-stage switching resistor module among the switching resistor modules is coupled to the first node. Each of the switching resistor modules is controlled by at least one corresponding signal in the first signal set to change the resistance of the first controllable resistor.
In an embodiment of the invention, each of the switching resistor modules includes a resistor module and a switch module. The switch module is connected in parallel with the resistor module. The switch module is controlled by the at least one corresponding signal in the first signal set to determine a resistance of the switching resistor module.
In an embodiment of the invention, the resistor module includes one or more resistors sequentially connected in series or connected in parallel with one another. The switch module includes one or more switches sequentially connected in series, and the switches are turned on/turned off respectively according to at least one corresponding signal in the second signal set.
In an embodiment of the invention, the second controllable resistor includes a plurality of switching resistor modules sequentially connected in series. A first-stage switching resistor module among the switching resistor modules is coupled to the first node. A last-stage switching resistor module among the switching resistor modules is coupled to the ground potential. Each of the switching resistor modules is controlled by the at least one corresponding signal in the second signal set to change the resistance of the second controllable resistor.
In an embodiment of the invention, the control circuit includes an edge detecting circuit, a counter and a sampling circuit. The edge detecting circuit is configured to receive the dimming signal, and detects a rising edge and a falling edge of the dimming signal to generate a reset signal. The counter is configured to receive an input clock signal and coupled to the edge detecting circuit to receive the reset signal. The counter generates a count value in response to the input clock signal and resets the count value in response to the reset signal. The sampling circuit is configured to receive the dimming signal and coupled to the counter to receive the count value. The sampling circuit samples the count value according to the falling edge of the dimming signal to serve as the second signal set and samples the count value according to the rising edge of the dimming signal to serve as the first signal set.
According to an embodiment of the invention, an LED backlight module including at least one LED string and the above-mentioned LED driving apparatus are provided. The LED driving apparatus is coupled to the at least one LED string to drive the at least one LED string.
To sum up, in the LED backlight module and the driving apparatus thereof provided by the embodiments of the invention, the control circuit can count the time lengths of the disable period and the enable period of the dimming signal to generate the first signal set and the second signal set, respectively. The adjustable voltage-divider circuit can adjust the dividing ratio thereof according to the first signal set and the second signal set to generate the reference voltage. The reference voltage generated according to the dividing ratio can substantially represent a duty cycle of the dimming signal. Thereby, the driving apparatus can convert the PWM-based dimming signal into the reference voltage without connecting external capacitors. In this way, the dimming signal at a low frequency can also be accurately converted into the reference voltage. Additionally, as the duty cycle of the dimming signal is changed, the reference voltage is also changed, such that the feedback voltage and a current flowing through the LED string are also changed accordingly, and the brightness of the LED string can be accurately adjusted.
In order to make the aforementioned and other features and advantages of the invention more comprehensible, several embodiments accompanied with figures are described in detail below.
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
Reference will now be made in detail to the exemplary embodiments of the disclosure, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers are used in the drawings and the description-Refer to the same or like parts.
Additionally, the driving apparatus 100 is coupled to the LED string 500 to drive the LED string 500. As illustrated in
A first input terminal of the comparator 140 is coupled to the first terminal of the sensing resistor Rs to receive the feedback voltage Vfb, a second input terminal of the comparator 140 is coupled to the adjustable voltage-divider circuit 120 to receive the reference voltage Vref, and an output terminal of the comparator 140 is configured to generate a control signal CS. The power converter 160 is coupled between the output terminal of the comparator 140 and an anode of the LED string 500. The power converter 160 is configured to receive an input voltage VIN. The power converter 160 performs a boost-buck process on the received input voltage VIN according to the control signal CS and adopting a pulse width modulation (PWM) control mechanism to provide a DC voltage VBUS to the anode of the LED string 500.
The control circuit 180 is coupled to the adjustable voltage-divider circuit 120. The control circuit 180 is configured to receive a dimming signal DIM. The control circuit 180 counts a disable period of the dimming signal DIM to generate the first signal set SC11-SC1y and counts enable period of the dimming signal DIM to generate the second signal set SC21-SC2x.
In overall operation, the control circuit 180 counts the disable period and the enable period of the dimming signal DIM to generate the first signal set SC11-SC1y and the second signal set SC21-SC2x, respectively. Thus, a value represented by the first signal set SC11-SC1y is correlated to a time length of the disable period of the dimming signal DIM, and a value represented by the second signal set SC21-SC2x is correlated to a time length of the enable period of the dimming signal DIM. Additionally, the adjustable voltage-divider circuit 120 adjusts the dividing ratio to generate the reference voltage Vref according to the first signal set SC11-SC1y and the second signal set SC21-SC2x. Thus, a voltage level of the reference voltage Vref generated according to the dividing ratio may substantially represent a duty cycle of the dimming signal DIM. Accordingly, the dimming signal DIM may be converted into the reference voltage Vref through the control circuit 180 and the adjustable voltage-divider circuit 120. In other words, the driving apparatus 100 provided by the invention may achieve converting the dimming signal DIM into the reference voltage Vref without connecting any external capacitor.
Then, the comparator 140 compares the reference voltage Vref and the feedback voltage Vfb to generate the control signal CS. The power converter 160 adjusts and provides the DC voltage VBUS according to the control signal CS. In detail, when the DC voltage VBUS is dropped, the feedback voltage Vfb sensed by the sensing resistor Rs is also dropped. When the feedback voltage Vfb is lower than the reference voltage Vref, the power converter 160 adjusts the DC voltage VBUS according to the control signal CS to rise a voltage level of the DC voltage VBUS, such that a voltage level of the feedback voltage Vfb is increased and maintained at the voltage level of the reference voltage Vref, and vice versa.
From the other perspective, when the duty cycle of the dimming signal DIM is changed, the voltage level of the reference voltage Vref is also changed, such that the feedback voltage Vfb is also changed (because the feedback voltage Vfb is maintained at the voltage level of the reference voltage Vref). In response to the feedback voltage Vfb, the current IL flowing through the LED string 500 is also changed (i.e., the current IL=Vfb÷Rs), and thereby, the brightness of the LED string 500 is changed as well. Accordingly, the dimming of the LED string 500 can be achieved through adjusting the duty cycle of the dimming signal DIM.
In an embodiment of the invention, the power converter 160 may be implemented by using a boost circuit or a buck circuit, but the invention is not limited thereto. The power converter 160 of the invention may also be implemented by using other power converting circuits.
Referring to
Specially, the first controllable resistor 122 is controlled by the first signal set SC11-SC1y to adjust a resistance of the first controllable resistor 122, and the second controllable resistor 124 is controlled by the second signal set SC21-SC2x to adjust a resistance of the second controllable resistor 124. Furthermore, an equivalent resistance of the first controllable resistor 122 is positively correlated to the time length of the disable period of the dimming signal DIM, and an equivalent resistance of the second controllable resistor 124 is positively correlated to the time length of the enable period of the dimming signal DIM.
In an embodiment of the invention, the first controllable resistor 122 includes Y switching resistor modules R11-R1y. Referring to
In other embodiments of the invention, each of the switching resistor modules R11-R1y may also be controlled by a plurality of corresponding signals in the first signal set SC11-SC1y to change the resistance of the first controllable resistor 122. For example, if the switching resistor module R11 determines a resistance of the switching resistor module R11 according to whether a plurality of switches therein is turned on, then the switching resistor module R11 may also be controlled by a plurality of corresponding signals in the first signal set SC11-SC1y to change the resistance of the first controllable resistor 122.
It is to be noted that in the exemplary embodiments described above, the number, Y, of the switching resistor modules R11-R1y may be a positive integer greater than 1, and the number Y may be determined based on actual application or design requirements. It may be understood that the greater the number Y is, the higher the resolution with respect to the resistance of the first controllable resistor 122 is, and thus, the reference voltage Vref generated by the adjustable voltage-divider circuit 120 will be more accurate.
Description with respect to the switching resistor modules R11-R1y will be set forth hereinafter. The switching resistor module R11 includes a resistor module RM11 and a switch module WM11. The switch module WM11 is connected in parallel with the resistor module RM11 and controlled by the corresponding signal (i.e., SC11) in the first signal set SC11-SC1y to determine the resistance of the switching resistor module R11. The switching resistor module R12 includes a resistor module RM12 and a switch module WM12. The switch module WM12 is connected in parallel with the resistor module RM12 and controlled by the corresponding signal (i.e., SC12) in the first signal set SC11-SC1y to determine the resistance of the switching resistor module R12. Likewise, the switching resistor module R1y includes a resistor module RMly and a switch module WM1y. The switch module WM1y is connected in parallel with the resistor module RMly and controlled by the corresponding signal (i.e., SC1y) in the first signal set SC11-SC1y to determine the resistance of the switching resistor module R1y. The others may be deduced in the same way.
Due to the switching resistor modules R11-R1y having the similar structures and operations, the resistor module RM11 and the switch module WM11 of the switching resistor module R11 will be described for example below, and the structures and the operations of the rest, i.e., the switching resistor modules R12-R1y, may be inferred in the same way.
In an embodiment of the invention, the resistor module RM11 may include one or more resistors. If the resistor module RM11 has a plurality of resistors, the resistors may be sequentially connected in series or connected in parallel with one another. The switch module WM11 may include one or more switches. If the switch module WM11 has a plurality of switches, the switches may be sequentially connected in series, and the switches may be turned on or turned off respectively according to the corresponding signals (e.g., SC11) in the first signal set SC11-SC1y.
It may be understood that when the switch module WM11 of the switching resistor module R11 is turned on, a short circuit occurs to the two terminals of the resistor module RM11 as the switch module WM11 is turned on, and thus, an effective resistance of the switching resistor module R11 may be substantially considered as 0 ohm (Ω). On the contrary, when the switch module WM11 of the switching resistor module R11 is turned off, the effective resistance of the switching resistor module R11 is substantially the resistance of the resistor module RM11. In this way, the turning on/turning off of the switch modules WM11-WM1y may be controlled through the first signal set SC11-SC1y, so as to adjust the resistance of the first controllable resistor 122.
In an embodiment of the invention, the second controllable resistor 124 includes X switching resistor modules R21-R2x. Referring to
In other embodiments of the invention, each of the switching resistor modules R21-R2x may also be controlled by a plurality of corresponding signals in the second signal set SC21-SC2x to change the resistance of the second controllable resistor 124. For example, if the switching resistor module R21 determines a resistance of the switching resistor module R21 according to whether a plurality of switches therein is turned on, then the switching resistor module R21 may also be controlled by a plurality of corresponding signals in the second signal set SC21-SC2x to change the resistance of the resistance of the second controllable resistor 124.
It is to be noted that in the exemplary embodiments described above, the number, X, of the switching resistor modules R21-R2x may be a positive integer greater than 1, and the number X may be determined based on actual application or design requirements. It may be understood that the greater the number X is, the higher the resolution with respect to the resistance of the second controllable resistor 124 is, and thus, the reference voltage Vref generated by the adjustable voltage-divider circuit 120 will be more accurate.
Description with respect to the switching resistor modules R21-R2x will be set forth hereinafter. The switching resistor module R21 includes a resistor module RM21 and a switch module WM21. The switch module WM21 is connected in parallel with the resistor module RM21 and controlled by the corresponding signal (i.e., SC21) in the second signal set SC21-SC2x to determine the resistance of the switching resistor module R21. The switching resistor module R22 includes a resistor module RM22 and a switch module WM22. The switch module WM22 is connected in parallel with the resistor module RM22 and controlled by the corresponding signal (i.e., SC22) in the second signal set SC21-SC2x to determine the resistance of the switching resistor module R22. Likewise, the switching resistor module R2x includes a resistor module RM2x and a switch module WM2x. The switch module WM2x is connected in parallel with the resistor module RM2x and controlled by the corresponding signal (i.e., SC2x) in the second signal set SC21-SC2x to determine the resistance of the switching resistor module R2x. The others may be deduced in the same way.
Due to the switching resistor modules R21-R2x having the similar structures and operations, the resistor module RM21 and the switch module WM21 of the switching resistor module R21 will be described for example below, and the structures and the operations of the rest, i.e., the switching resistor modules R12-R1y, may be inferred in the same way.
In an embodiment of the invention, the resistor module RM21 may include one or more resistors. If the resistor module RM21 has a plurality of resistors, the resistors may be sequentially connected in series or connected in parallel with one another. The switch module WM21 may include one or more switches. If the switch module WM21 has a plurality of switches, the switches may be sequentially connected in series, and the switches may be turned on or turned off respectively according to the corresponding signals (e.g., SC21) in the second signal set SC21-SC2x.
It may be understood that when the switch module WM21 of the switching resistor module R21 is turned on, a short circuit occurs to the two terminals of the resistor module RM21 as the switch module WM21 is turned on, and thus, an effective resistance of the switching resistor module R21 may be substantially considered as 0Ω On the contrary, when the switch module WM21 of the switching resistor module R21 is turned off, the effective resistance of the switching resistor module R21 is substantially the resistance of the resistor module RM21. In this way, the turning on/turning off of the switch modules WM21-WM2x may be controlled through the second signal set SC21-SC2x so as to adjust the resistance of the second controllable resistor 124.
Referring to both
It is to be mentioned that resistances of the resistor modules RM11-RM17 of the switching resistor modules R11-R17 may be 8r, 4r, 2r, r, (½)r, (¼)r and (⅛)r, respectively, and resistances of the resistor modules RM21-RM27 of the switching resistor modules R21-R27 may be 8r, 4r, 2r, r, (½)r, (¼)r and (⅛)r, respectively. It assumed herein that the switch modules WM11 to WM17 may be turned off respectively in response to the first signal set SC11-SC17 with logic “1” and may be turned on respectively in response to the first signal set SC11-SC17 with logic “0”. Therefore, when disable period of the dimming signal DIM is gradually increased that a value represented by the first signal set SC11-SC17 obtained through counting by the control circuit 180 is also increased, a value represented by the first signal set SC11-SC17 is changed from a binary value “0000001” (whose decimal value is 1) to a binary value “0000010” (whose decimal value is 2), such that a resistance of the first controllable resistor 122′ rises up from (⅛)r to (¼)r. Accordingly, the resistance of the first controllable resistor 122′ is substantially proportional to the time length of the disable period of the dimming signal DIM. Likewise, a resistance of the second controllable resistor 124′ is substantially proportional to the time length of the enable period of the dimming signal DIM.
It may be understood that each of the resistor modules RM11 and RM21 may be formed by 8 resistors each with a resistance of r connected in series; each of the resistor modules RM12 and RM22 may be formed by 4 resistors each with a resistance of r connected in series; each of the resistor modules RM13 and RM23 may be formed by 2 resistors each with a resistance of r connected in series; each of the resistor modules RM15 and RM25 may be formed by 2 resistors each with a resistance of r connected in parallel; each of the resistor modules RM16 and RM26 may be formed by 4 resistors each with a resistance of r connected in parallel; and each of the resistor modules RM17 and RM27 may be formed by 8 resistors each with a resistance of r connected in parallel, but the invention is not limited thereto.
Referring to
Referring to
In an embodiment of the invention, the edge detecting circuit 482, the counter 484 and the sampling circuit 486 of the control circuit 180 may be implemented in a form of hardware, such as application-specific integrated circuits (ASIC) or field programmable gate array (FPGA), but the invention is not limited thereto. In other embodiments of the invention, the control circuit 180 may also be implemented in a form of software programs executed by microprocessors or digital signal processors (DSP), for example.
To summarize, in the LED backlight module and the driving apparatus thereof provided by the embodiments of the invention, the control circuit can count the time lengths of the disable period and the enable period of the dimming signal, so as to generate the first signal set and the second signal set, respectively. The adjustable voltage-divider circuit can adjust the dividing ratio according to the first signal set and the second signal set to generate the reference voltage. The reference voltage generated according to the dividing ratio can substantially represent the duty cycle of the dimming signal. Thus, the driving apparatus can achieve converting the PWM-based dimming signal into the reference voltage without connecting any external capacitor. In this way, the dimming signal even at a low frequency can be accurately converted into the reference voltage. In addition, as the duty cycle of the dimming signal is changed, the reference voltage is also changed, such that the feedback voltage and the current flowing through the LED string are also changed. Therefore, the brightness of the LED string can be accurately adjusted.
Although the invention has been described with reference to the above embodiments, it will be apparent to one of the ordinary skill in the art that modifications to the described embodiment may be made without departing from the spirit of the invention. Accordingly, the scope of the invention will be defined by the attached claims not by the above detailed descriptions.
| Number | Date | Country | Kind |
|---|---|---|---|
| 104129473 A | Sep 2015 | TW | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 6636003 | Rahm | Oct 2003 | B2 |
| 20090134817 | Jurngwirth | May 2009 | A1 |
| 20090224736 | Santo | Sep 2009 | A1 |
| 20120074860 | Lee | Mar 2012 | A1 |
| 20130342124 | Huang | Dec 2013 | A1 |
| Number | Date | Country |
|---|---|---|
| 102244965 | Nov 2011 | CN |
| 103517503 | Jan 2014 | CN |
| 201138553 | Nov 2011 | TW |
| 201526572 | Jul 2015 | TW |
| Entry |
|---|
| “Office Action of Taiwan Counterpart Application”, issued on Jul. 25, 2016, p. 1-p. 3. |
