Embodiments of the present disclosure relate to systems of backlight modulation circuits that are used in liquid crystal displays (LCDs), and more particularly to systems and methods of a backlight modulation circuit with rough and fine modulation functions.
Because LCDs have the advantages of portability, low power consumption, and low radiation, they have been widely used in various portable information products such as notebooks, personal digital assistants (PDAs), video cameras, etc.
A conventional LCD typically includes a liquid crystal panel, a backlight module with a plurality of light sources for illuminating the LCD panel, and a backlight modulation circuit for modulating illumination provided by the backlight module.
Referring to
In a digital method for modulating illumination provided by a backlight module, pulse width modulation (PWM) and pulse frequency modulation (PFM), may be used.
One drawback of the above-described analog and digital PWM methods is that they can only modulate the illumination provided by the backlight module either in a large and imprecise range or in a small and precise range. However, if an LCD needs to be modulated in a large and precise range, then many modulation commands and signals may need to be analyzed. Accordingly, modulating the many commands and signals wastes valuable processor cycles and consumes additional energy.
It is desired to provide a new backlight modulation circuit and a method for modulating illumination of a light source which can overcome the above-described deficiencies.
In one aspect, a backlight modulation circuit comprises: an illumination controlling signal generating circuit configured for receiving a modulation signal and generating an illumination controlling signal according to the modulation signal; an illumination control signal separating circuit configured for separating the illumination controlling signal into a first modulation signal and a second modulation signal; and an illumination modulation circuit configured for modulating illumination of a backlight module according to the first and second modulation signals.
In another aspect, the aforementioned needs are satisfied by a method for modulating illumination of a light source, the method comprising: receiving an external modulation signal; generating an illumination controlling signal according to the external modulation signal; separating the illumination controlling signal into a first modulation signal and a second modulation signal; and modulating an illumination of the light source according to the first and second modulation signals.
Other novel features and advantages of the backlight modulation circuit and related method will become more apparent from the following detailed description when taken in conjunction with the accompanying drawings.
Reference will now be made to the drawings to describe various inventive embodiments of the present disclosure in detail, wherein like numerals refer to like elements throughout.
As used herein, the term, “fine modulation signal” refers to a modulation signal with a substantially constant period and a substantially constant amplitude. As used herein, the term, “rough modulation signal” refers to a modulation signal with varying amplitudes and varying periods between the varying amplitudes.
It may be understood that the signal processing circuit 31 may receive one or more modulation signals from an external device electrically coupled to the signal processing circuit 31. The modulation signal may include rough and/or fine modulating signal(s) to be processed by the signal processing circuit 31. It is to be further appreciated that a signal may comprise a control bit and a data bit. The control bit may comprise a binary number (i.e. 1 or 0), while the data bit may comprise one or more binary numbers comprising a modulation signal.
After the signal processing unit 31 and the illumination control generating circuit 32 process the modulation signal into an illumination control signal, the illumination control signal is transmitted to the illumination control signal separating circuit 34 via the illumination control signal receiving circuit 33. In the illumination control signal separating circuit 34, a rough modulation signal is separated from the illumination control signal using the square wave amplitude separating circuit 341, the integrating and smoothing circuit 342, and the amplifying circuit 343. Furthermore, a fine modulation signal is separated from the illumination control signal using the duty ratio separating circuit 344 and the fine modulation signal processing circuit 345. The selection circuit 35 selects one of the rough and fine modulation signals, altered by the illumination control separating circuit 34, and sends the selected signal to the illumination modulation circuit 36. The illumination modulation circuit 36 modulates illumination of the light source according to the received fine or rough modulation signal. Further details of receiving and processing a modulation signal will be explained below in more detail with respect to the flowchart of
In step S1, the signal processing circuit 31 receives a modulation signal from an external device, such as a keyboard, or a remote controller, for example.
In step S2, a signal type of the modulation signal is determined by the signal processing circuit 31. Step S2 can be divided into sub-step S2a and sub-step S2b.
In step S2a, the signal processing circuit 31 determines whether the signal is a rough modulation signal. If the determination is “yes”, then the method proceeds to step S3b, which is described below. If the determination is “no”, then the method proceeds to step S2b.
In step S2b, the signal processing circuit 31 determines whether the signal is a fine modulation signal. If the determination is “yes”, then the method proceeds to step S3a, which is described below. If the determination is “no”, then the method proceeds back to step S1.
In step S3, the illumination control signal generating circuit 32 generates an illumination control signal according to the modulation signal.
In sub-step S3a, the illumination control signal generating circuit 32 generates a first square wave signal which is shown as part A of the illumination control signal in
In sub-step S3b, the illumination control signal generating circuit 32 generates a second square wave signal which is shown as the part B of the illumination control signal in
After steps S3a and S3b are carried out, the method proceeds to step S4. In step S4, the illumination control signal receiving circuit 33 receives the illumination control signal, and sends the illumination control signal to the illumination control signal separating circuit 34.
In step S5, the illumination control signal separating circuit 34 separates the illumination control signal into a rough modulation signal and a fine modulation signal. Step S5 is divided into sub-step S5a and sub-step S5b.
In sub-step S5a, the rough modulation signal is separated from the illumination control signal by the square wave amplitude separating circuit 341, the integrating and smoothing circuit 342, and the amplifying circuit 343. In one embodiment, the rough modulation signal may be expressed according to the following equation:
U=(Um*Tm+Us*Ts)/T
where Tm represents a time period of the primary amplitude Um in a time period T, Ts represents a time period of the secondary amplitude Us in a time period T, and U represents a voltage value of the rough modulation signal.
The voltage value U is amplified K times to obtain a rough modulation signal KU, which is shown as the fourth curve in
In sub-step S5b, the fine modulation signal is separated from the illumination control signal via the duty ratio separating circuit 344. In one embodiment, the fine modulation signal may correspond to the primary amplitude portion Tm of the illumination control signal. Then the method proceeds to step S6.
In step S6, the fine modulation signal is processed by the fine modulation signal processing circuit 345. Step S6 is divided into sub-step S6a, sub-step S6b, and sub-step S6c.
In sub-step S6a, the fine modulation signal processing circuit 345 determines whether a duty ratio of the fine modulation signal has been changed. If the answer is “yes”, the method proceeds to sub-step S6b. If the answer is “no”, the method proceeds to sub-step S6c.
In sub-step S6b, a control bit of the fine modulation signal is set as “1”. Then the method proceeds to step S7.
In sub-step S6c, a control bit of the fine modulation signal is set as “0”. Then the method proceeds to step S7.
In step S7, the selection circuit 35 selects either one of the rough modulation signal or the fine modulation signal as a final modulation signal. In one example, if the control bit of the fine modulation signal is “1”, then the selection circuit 35 selects the fine modulation signal and sends it to the illumination modulation circuit 36. In another example, if the control bit of the fine modulation signal is “0”, then the selection circuit 35 selects the rough modulation signal and sends it to the illumination modulation circuit 36.
In step S8, illumination of a light source is modulated by the illumination modulation circuit 36 according to the received modulation signal in step S7. In one example, if the illumination modulation circuit 36 receives the rough modulation signal, then the illumination modulation circuit 36 may rapidly change a driving voltage of the light source to vary in a large range. Thus, illumination of the light source can be modulated in a large range within a short time period. In another example, if the illumination modulation circuit 36 receives the rough modulation signal, then the illumination modulation circuit 36 may slowly change a driving voltage of the light source to vary in a small range. Thus, the illumination of the light source can be precisely modulated in a small range.
The backlight modulation circuit 300 is able to process both a rough modulation signal and a fine modulation signal in the same time period. Thus illumination of the backlight module can be modulated precisely once in a short time period. This provides convenience and saves operational time.
After processing a rough and a fine modulation signal by the signal processing circuit 31, the illumination control signal generating unit 32, and the illumination control signal receiving unit 33, an illumination control signal is transmitted to the illumination control signal separating circuit 37. In the illumination control signal separating circuit 37, a rough modulation signal is separated from the illumination control signal by the square wave amplitude separating circuit 341, the integrating and smoothing circuit 342, the amplifying circuit 343, and the rough modulation signal processing circuit 445. A fine modulation signal is separated from the illumination control signals via the duty ratio separating circuit 344. Then the selection circuit 35 selects one of the rough and fine modulation signals which is changed, and sends the fine/rough modulation signal to the illumination modulation circuit 36, and sends the selected one of the fine and rough modulation signals to the illumination modulation circuit 36. Then the illumination modulation circuit 36 modulates illumination of the light source according to the fine/rough modulation signal.
In the flowchart of
In step S46, the fine modulation signal is processed by the rough modulation signal processing circuit 445. Step S46 is divided into sub-step S46a, sub-step S46b, and sub-step S46c.
In sub-step S46a, the rough modulation signal processing circuit 445 determines whether an amplitude of the rough modulation signal is changed in a predetermined time period. If the answer is “yes”, the method proceeds to sub-step S46b. If the answer is “no”, the method proceeds to sub-step S46c.
In sub-step S46b, a control bit of the rough modulation signal is set as “1”. Then the method proceeds to step S47.
In sub-step S46c, a control bit of the rough modulation signal is set as “0”. Then the method proceeds to step S47.
In step S47, the selection circuit 35 selects either one of the rough modulation signal or the fine modulation signal as a final modulation signal. In one example, if the control bit of the rough modulation signal is “1”, then the selection circuit 35 selects the rough modulation signal and sends it to the illumination modulation circuit 36. In another example, if the control bit of the rough modulation signal is “0”, then the selection circuit 35 selects the fine modulation signal and sends it to the illumination modulation circuit 36.
In step S48, illumination of a light source is modulated by the illumination modulation circuit 36 according to the final modulation signal. If the illumination modulation circuit 36 receives the rough modulation signal, then the illumination modulation circuit 36 controls the driving circuit to rapidly change a driving voltage of the light source in a large range; thereby, illumination of the light source can be modulated in a large range within a short time. If the illumination modulation circuit 36 receives the fine modulation signal, then the illumination modulation circuit 36 controls the driving circuit to change a driving voltage of the light source slowly in a small range; thereby, the illumination of the light source can be modulated precisely in a small range.
It is to be understood, however, that even though numerous characteristics and advantages of certain inventive embodiments have been set out in the foregoing description, together with details of the structures and functions of the embodiments, the disclosure is illustrative only; and that changes may be made in detail, especially in matters of arrangement of parts within the principles of present invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
Number | Date | Country | Kind |
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200710075200.3 | Jun 2007 | CN | national |