The present invention relates to backlight modulation circuits for liquid crystal displays (LCDs), and particularly to a backlight modulation circuit with coarse and fine modulation functions and a related backlight illumination modulation method.
A typical LCD has the advantages of portability, low power consumption, and low radiation. LCDs have been widely used in various portable information products such as notebooks, personal digital assistants (PDAs), video cameras and the like. Furthermore, the LCD is considered by many to have the potential to completely replace CRT (cathode ray tube) monitors and televisions.
A conventional LCD typically includes a liquid crystal panel, a backlight module illuminating the LCD panel, and a backlight modulation circuit modulating illumination of the backlight module.
The signal processing section 120 includes an input terminal 121 configured to receive an external command. The signal processing section 120 converts the external command to a backlight modulation signal, and outputs the backlight modulation signal to the signal modulation section 130. After receiving the backlight modulation signal, the signal modulation section 130 modulates a backlight driving signal controlling the illumination of the backlight module, via a pulse width modulation (PWM) or pulse frequency modulation (PFM) method according to the backlight modulation signal. A modulated backlight driving signal is output to the backlight modulation section 140. Accordingly, the backlight modulation section 140 modulates the illumination of the backlight module, thereby achieving an appropriate illumination level for the LCD.
The backlight modulation circuit 1, having only one signal processing channel, can only process one kind of backlight modulation signal at a time, typically a coarse modulation signal or a fine modulation signal. Thus regulating of the illumination of the backlight module by the backlight modulation circuit 1 can only be achieved in one of a large, broad range or a small, precise range at any one time. That is, if illumination of an LCD employing the backlight modulation circuit 1 is to be modulated in both a large range and a precise range, the backlight modulation circuit 1 must modulate the illumination twice via two separate modulation commands. This is inefficient and time-consuming.
It is thus desired to provide a new backlight modulation circuit and a backlight modulation method which can overcome the limitations described.
In one exemplary embodiment, a backlight modulation circuit includes a first modulation section, a second modulation section, and a backlight modulation section. The first modulation section is configured to generate a first backlight modulation signal. The second modulation section is configured to generate a second backlight modulation signal. The backlight modulation section is configured to modulate illumination of an associated backlight module according to the first and second backlight modulation signals.
Other novel features and advantages of the backlight modulation circuit 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 embodiments of the present invention in detail.
The signal processing section 210 includes a first input terminal 211, a second input terminal 212, a first output terminal 213, and a second output terminal 214. The first and second input terminals 211, 212 are configured to receive a coarse modulation command and a fine modulation command respectively from an external device (not shown), such as a keyboard, a remote controller, and the like. The first output terminal 213 and the second output terminal 214 are electrically coupled to the coarse modulation section 220 and the fine modulation signal generation section 221, respectively.
The coarse modulation section 220, the first integration circuit 230, and the magnifying circuit 260 are electrically coupled in series in that order. The fine modulation signal generation section 221 and the second integration circuit 231 are electrically coupled in series. Both the amplifying circuit 260 and the second integration circuit 231 are electrically coupled to the summing circuit 270. The summing circuit 270 is electrically coupled to the backlight modulation section 240.
In step S1, the first and second input terminals 211, 212 receive a coarse modulation command and a fine modulation command respectively from an external device. The coarse modulation command and fine modulation command are processed and converted to a corresponding coarse modulation controlling signal and a corresponding fine modulation controlling signal by the signal processing section 210, respectively. Then the coarse modulation controlling signal and the fine modulation controlling signal are output via the first and second output terminals 213, 214, respectively.
In step S2, the coarse modulation section 220 receives the coarse modulation controlling signal from the first output terminal 213. According to the coarse modulation controlling signal, the coarse modulation section 220 generates and modulates a backlight driving signal using a PWM method, thereby forming a digital coarse modulation signal. The coarse modulation signal, with a relatively large duty ratio, corresponds to a higher illumination of the backlight module; and the coarse modulation signal, with a relatively small duty ratio, corresponds to a lower illumination of the backlight module. After the modulation process, the coarse modulation section 220 analyzes the coarse modulation signal, to determine whether the modulation range of the coarse modulation signal is beyond the modulation range of the backlight module. If the determination is “yes”, the illumination of the backlight module is modulated to a maximum value. If the determination is “no”, the illumination of the backlight module is modulated in accordance with the coarse modulation signal. Then, the coarse modulation section 220 outputs the coarse modulation signal to the first integration circuit 230.
Simultaneously, the fine modulation signal generation section 221 receives the fine modulation controlling signal from the second output terminal 214. According to the fine modulation controlling signal, the fine modulation section 221 generates and modulates a backlight driving signal also using a PWM method, thereby forming a digital fine modulation signal. The fine modulation signal, with a relatively large duty ratio, corresponds to a higher illumination of the backlight module; and the fine modulation signal, with a relatively small duty ratio, corresponds to a lower illumination of the backlight module. After the modulation process, the fine modulation section 221 analyzes the fine modulation signal, to determine whether the modulation range of the fine modulation signal is beyond a coarse modulation precision, which is the minimum coarse modulation value. If the determination is “yes”, the minimum coarse modulation value is subtracted from the fine modulation value, with the result set as a final fine modulation value. If the determination is “no”, the fine modulation value is directly set as the final fine modulation value. The fine modulation signal generation section 221 then outputs the fine modulation signal to the second integration circuit 231.
In step S3, the first integration circuit 230 receives and integrates the coarse modulation signal, thereby obtaining an analog coarse modulation signal. The analog coarse modulation signal is then transmitted to the amplifying circuit 260. The amplifying circuit 260 amplifies the analog coarse modulation signal by an appropriate multiple, and the amplified analog coarse modulation signal is transmitted to the summing circuit 270.
Simultaneously, the second integration circuit 231 receives and integrates the fine modulation signal, thereby obtaining an analog fine modulation signal. The analog fine modulation signal is then transmitted to the summing circuit 270.
Then summing circuit 270 adds the fine modulation signal to the coarse modulation signal, and outputs a complex modulation signal having both the coarse and fine modulation signals to the backlight modulation section 240.
In step S4, the backlight modulation section 240 receives the complex modulation signal and modulates the illumination of the backlight module accordingly.
Unlike the conventional backlight modulation circuit, the backlight modulation circuit 2 includes both a coarse modulation section 220 and a fine modulation section 221. The coarse modulation section 220 and the fine modulation section 221 generate coarse and fine modulation signals, respectively. The coarse modulation signal and the fine modulation signal are added together into a complex modulation signal, used by the backlight modulation section 240 to modulate illumination of the backlight module. The complex modulation signal is a combination signal including both coarse and fine modulation information, whereby illumination of the backlight module can be modulated precisely in a short time. Convenience is increased and operating time conserved.
It is to be understood, however, that even though numerous characteristics and advantages of various embodiments have been set out in the foregoing description, together with details of 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 the present invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
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