JP2005346081A - Display device equipped with control module for preventing harmonic disturbance - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To overcome unevenness phenomenon, by providing a display device equipped with a control module for preventing harmonic disturbances. <P>SOLUTION: The display device is adapted to receive an image signal having an image scanning frequency and includes an internal light source, a light source adjustment module, and a control module. The light source adjustment module has a pulse width modulation controller, generating an origin control signal, the control module has a frequency detection circuit and a plurality of range adjustment circuits. The frequency detection circuit controls the pulse width modulation controller, by operating one among the range adjustment circuits. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a display device, and more particularly to a display device including a control module that prevents harmonic interference.

  Flat panel display (FPD) devices, such as liquid crystal displays (LCDs), back projection displays, and projector devices, have become the trend of display devices. In such an FPD device, for example, a conventional LCD device includes a display panel that controls the operation of the backlight source module, a backlight source module, and a light source adjustment module (such as an inverter).

As shown in FIG. 1, adjustment of brightness and contrast in the LCD device is generally realized through adjustment of the amplitude (a) of the power signal 101 applied to the backlight source module. In actual measurement, the adjustment of the amplitude (a) between the maximum and minimum values, a narrow range of tunable brightness value, i.e., only result in 250 cd / ^{m 2} to 180 cd / ^{m 2.}

  Referring to FIG. 2, an LSD device capable of operating in burst mode includes a power circuit 30, a control unit 31, a transformer unit 32, a feedback unit 33, and a set of light sources 34 (such as lamp tubes). Illustrated.

  Unlike the control mechanism of FIG. 1, when the amplitude of the power supply signal is adjusted to the minimum value, the control unit 31 operates in the burst mode, receives the square wave signal 301 whose width is adjustable, and the light source control signal 201. And the light source 34 is controlled via the transformer unit 32 and the feedback unit 33 according to the square wave 301.

In the burst mode, power to the light source 34 is intermittently interrupted according to the square wave signal 301. As shown in FIG. 3, the time of the source control signal 201 from the control unit 31 in which the light source 34 is continuously turned on and off is continuously controlled, resulting in an afterimage. Therefore, a minimum luminance output can be obtained with the visual sense of the light source 34, while time (d) corresponds to the turn-off period of the light source 34. By adjusting the length of the period (d) up to the period (D), a wider range of adjustable brightness values, for example, 250 cd / m ^{2 to} 50 cd / m ² is obtained.

  However, during the process of adjusting the source control signal 201, harmonics are generated if the resulting turn-on or turn-off of the light source 34 was an integer multiple of the display scan frequency. This results in a mura phenomenon on the display panel and thus adversely affects the image quality exhibited by the LCD device. Similar unevenness also occurs in back projection displays and projector devices.

  Accordingly, the present invention aims to provide a display device having a control module for preventing harmonic interference, and to overcome the above-mentioned mura phenomenon associated with the prior art.

  Another object of the present invention is to provide a display device adapted to receive signals having different scanning frequencies. Such a display device includes a control module to prevent harmonic interference caused by the scanning frequency and the turn-on and turn-off frequency of the light source.

  Yet another object of the present invention is to provide a control module for use in a display device to prevent harmonic interference.

  According to one aspect of the invention, a display device is provided that is adapted to receive an image signal having a display scanning frequency and display an image corresponding to the image signal. The display device includes an internal light source, a light source adjustment module, and a control module.

  The light source adjustment module is electrically coupled to the internal light source and has a pulse width modulation controller. The controller is operable and is adapted to generate source control signals that control the turn-on and turn-off of the internal light source.

  The control module includes a frequency detection circuit that detects a display scanning frequency of the image signal, and a plurality of range adjustment circuits that are electrically coupled to the frequency detection circuit and the pulse width modulation controller, respectively. The frequency detection circuit activates one of the range adjustment circuits according to the detected display scanning frequency. Since the activated one of the range adjustment circuits controls the pulse width modulation controller, the pulse width modulation controller generates the source control signal within a preset frequency range. The preset frequency range corresponds to the activated one of the range adjustment circuits and has a turn-on and turn-off frequency that is not an integer multiple of the display scan frequency detected by the frequency detection circuit.

  According to another aspect of the invention, a control module is provided that prevents harmonic interference of the display device. Such a display device receives an image signal having a display scanning frequency and displays an image corresponding to the image signal. The display device includes an internal light source and a light source adjustment module that is electrically coupled to the internal light source and has a pulse width modulation controller. The pulse width modulation controller is operable and is adapted to generate a source control signal that controls the turn-on and turn-off of the internal light source.

  The control module includes a frequency detection circuit that detects a display scanning frequency of the image signal and a plurality of range adjustment circuits that are each electrically coupled to the frequency detection circuit and the pulse width modulation controller. The frequency detection circuit activates one of the range adjustment circuits according to the detected display scanning frequency. Since the activated one of the range adjustment circuits controls the pulse width modulation controller, the pulse width modulation controller generates the source control signal within a preset frequency range. The preset frequency range corresponds to the activated one of the range adjustment circuits and has a turn-on and turn-off frequency that is not an integer multiple of the display scan frequency detected by the frequency detection circuit.

  Other features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiments, taken in conjunction with the accompanying drawings.

  A preferred embodiment of the display device 10 according to the present invention is illustrated in FIGS. In the present embodiment, the display device 10 is a liquid crystal display device having a pair of lamp tubes 9 serving as an internal light source and a liquid crystal display (LCD) panel 5. In other embodiments, the display device of the present invention may be in the form of a back projection display device, a projection device, etc., and the internal light source may be a light emitting diode.

  The display device 10 is adapted to receive an image signal 702 having a display scanning frequency and to display an image corresponding to the image signal 702, and includes a light source adjustment module 8. The light source adjustment module 8 includes a power circuit 81, a pulse width modulation (PWM) controller 80 electrically coupled to the power circuit 81, an inverter 83 coupled to the PWM controller 80, an inverter 83, and a transformer coupled to the internal light source 9. And a feedback unit 85 coupled to the transformer 84 and the PWM controller 80. Since the PWM controller 80 can operate in burst mode, it allows a wide range of adjustable brightness values. When operating in burst mode, the PWM controller 80 generates a source control signal 801 that controls the turn-on and turn-off of the internal light source 9. The PWM controller 80 further includes a control terminal 802 that receives a control signal. Since the amplitude of the signal varies, the PWM controller 80 can generate the source control signal 801 within the corresponding frequency range. The structure and operation of inverter 83, transformer 84, and feedback unit 85 are well known to those skilled in the art and will not be described in further detail here for the sake of brevity.

  In the present embodiment, the display apparatus 10 further includes a control module 82 that controls the operation of the PWM controller 80. The control module 82 includes a frequency detection circuit 60 that detects a display scanning frequency of the image signal 702, and a plurality of range adjustment circuits 61, 62, and 63 that are electrically coupled to the frequency detection circuit 60 and the PWM controller 80, respectively. Including. In such an embodiment, the range adjustment circuits 61, 62, 63 are in the form of a switch circuit.

  In this embodiment, the LCD panel 5 of the display device 10 has been demonstrated to receive an image signal 702 from a processor 71 of a graphic display adapter card (hereinafter referred to as display card 7) of a personal computer. The image signal 702 has a specific display scanning frequency (eg, 75 Hz). The LCD panel 5 is adapted to respond to the image signal 702 in a known manner and display a corresponding image. In addition, the frequency detection circuit 60 is coupled to the display card 7 so that the display scanning frequency of the image signal 702 can be detected. The frequency detection circuit is operable, generates a status signal 701 corresponding to the detected display scanning frequency, and activates a corresponding one of the range adjustment circuits 61, 62, 63. Is done.

  To allow for a wide range of applications, the number of range adjustment circuits 61, 62, 63 is preferably at least a number of standard display scanning frequencies such as 56 Hz, 60 Hz, 72 Hz, and 85 Hz that are currently used. Correspond. Thus, in practice, there are at least five range adjustment circuits 61, 62, 63, each corresponding to one of the standard display scanning frequencies. For simplicity, only three range adjustment circuits 61, 62, 63 are illustrated in the drawing.

  The range adjustment circuits 61, 62, 63 are coupled to the frequency detection circuit 60 and controlled by the ground switch 611, 621, 631 and the ground switch 611, 621, 631 at one terminal. Capacitors 612, 622, 632 adapted to couple to the control terminal 802 of the PWM controller 80 at the other end of the terminal. The capacitors 612, 622, and 632 of the range adjustment circuits 61, 62, and 63 have different capacitance values, and the ground switches 611, 621, and 631 are typically open switches. The open switch closes only when activated by the presence of a status signal 701 in the dedicated control line from the frequency detection circuit 60.

  In the following illustrative example, it is assumed that the range adjustment circuits 61, 62, 63 are configured to correspond to standard display scanning frequencies that are 60 Hz, 75 Hz, and 85 Hz, respectively. When the frequency detection circuit 60 detects that the display scanning frequency of the image signal 702 is 60 Hz, the status signal 701 from the frequency detection circuit 60 operates the ground switch 611 of the range adjustment circuit 61, so that the corresponding capacitor 612 Grounded. As a result, the voltage at the control terminal 802 of the PWM controller 80 is adjusted so that the PWM controller is an integer multiple of the display scan frequency detected by the frequency detection circuit 60 (ie 60, 120, 180,. Output a pulsating source control signal 801 with turn-on and turn-off frequencies in the preset frequency range of 215 Hz and 225 Hz.

  On the other hand, when the frequency detection circuit 60 detects that the display scanning frequency of the image signal 702 is 75 Hz, the status signal 701 from the frequency detection circuit 60 activates the ground switch 621 of the range adjustment circuit 62, and thus corresponds. Capacitor 622 is grounded. As a result, the voltage at the control terminal 802 of the PWM controller 80 is adjusted so that the PWM controller is an integer multiple of the display scanning frequency detected by the frequency detection circuit 60 (ie, 75, 150, 225,. Output a pulsed source control signal 801 with turn-on and turn-off frequencies in the preset frequency ranges of 240 Hz and 255 Hz.

  Similarly, when the frequency detection circuit 60 detects that the display scanning frequency of the image signal 702 is 85 Hz, the status signal 701 from the frequency detection circuit 60 operates the ground switch 631 of the range adjustment circuit 63. Capacitor 632 is grounded. As a result, the voltage at the control terminal 802 of the PWM controller 80 is adjusted so that the PWM controller is an integer multiple of the display scan frequency detected by the frequency detection circuit 60 (ie, 85, 170, 255... Hz). Output a pulsating source control signal 801 with turn-on and turn-off frequencies within the preset frequency ranges of 230 Hz and 245 Hz.

  Based on the display scanning frequency detected by the frequency detection circuit 60, one of the ground adjustment switches 611, 621 and 631 among the range adjustment circuits 61, 62 and 63 is operated by the frequency detection circuit 60. Since the capacitors 612, 622, and 632 of the range adjustment circuits 61, 62, and 63 have different capacitance values, the voltage at the control terminal 802 of the PWM controller 80 changes according to the detected display scanning frequency. Therefore, the PWM controller 80 can generate the source control signal 801 within a preset frequency range. The preset frequency range corresponds to the activated one of the range adjustment circuits 61, 62, 63 and provides a turn-on and turn-off frequency that is not an integer multiple of the display scanning frequency detected by the frequency detection circuit 60. Have. As a result, harmonic interference and unevenness phenomenon associated with such interference can be prevented, so that the quality of the image displayed by the display device 10 is maintained.

  The image signal 702 may be generated by an audio-video signal source other than the display card 7. Further, in this embodiment, the capacitors 612, 622, 632 of the range adjustment circuits 61, 62, 63 have different capacitance values, so that the voltage at the control terminal 802 of the PWM controller 80 is in accordance with the detected display scanning frequency. Can be changed. However, in applications where the PWM controller 80 is made with a set of usable control terminals, the PWM controller 80 does not require the capacitors 612, 622, 632 and operates the range adjustment circuits 61, 62, 63. It can be configured to check the status and inactive state.

  The present invention has been described in connection with what is considered the most practical and preferred embodiment. On the other hand, the invention is not limited to the disclosed embodiments and is intended to cover a wide variety of arrangements included within the spirit and scope of the broadest interpretation so as to cover all such embodiments and equivalent arrangements. It is understood that it is intended.

2 illustrates a power signal for adjusting brightness and contrast in a conventional LCD device. 1 is a schematic circuit block diagram of a conventional LCD device operable in a burst mode. FIG. 3 illustrates a source control signal generated by the conventional LCD device in FIG. 1 is a schematic circuit block diagram of a preferred embodiment of a display device according to the present invention. FIG. 6 is another schematic circuit block diagram of the preferred embodiment, illustrating the control module in more detail.

Explanation of symbols

5 Display Panel 7 Display Card 8 Light Source Adjustment Module 9 Lamp Tube 10 Display Device 80 Pulse Width Modulation Controller 82 Control Module 81 Power Circuit 83 Inverter 84 Transformer 85 Feedback Unit 702 Image Signal 801 Source Control Signal 802 Control Terminal

Claims (10)

A display device (10) adapted to receive an image signal (702) having a display scanning frequency and to display an image corresponding to the image signal (702),
An internal light source (9);
A pulse width modulation controller (80) that is electrically coupled to the internal light source (9) and is operable to generate a source control signal (801) to control turn-on and turn-off of the internal light source (9) A light source adjustment module (8);
A frequency detection circuit (60) for detecting the display scanning frequency of the image signal (702), and a plurality of the frequency detection circuit (60) and a plurality of pulse width modulation controllers (80) electrically coupled to the frequency detection circuit (60). A control module (82) including a range adjustment circuit (61, 62, 63);
Have
The frequency detection circuit (60) operates one of the range adjustment circuits (61, 62, 63) according to the detected display scanning frequency,
Since the activated one of the range adjustment circuits (61, 62, 63) controls the pulse width modulation controller (80), the pulse width modulation controller (80) is connected to the range adjustment circuit (61). , 62, 63) corresponding to the activated one of the turn-on and turn-off frequencies that are not an integer multiple of the display scanning frequency detected by the frequency detection circuit (60). Generating the source control signal (801) in a frequency range;
Display device.   The display device (10) of claim 1, wherein the pulse width modulation controller (80) is operated in a burst mode. Each of the range adjustment circuits (61, 62, 63) is connected to the frequency detection circuit (60) and controlled by a ground switch (611, 621, 631), and the ground switch (611, 621, 631). And a capacitor coupled between the pulse width modulation controller (80),
The display device (10) according to claim 1.   The display device (10) according to claim 1, wherein the display device (10) is a liquid crystal display device and the internal light source (9) comprises a lamp tube or a light emitting diode.   The display device (10) of claim 1, wherein the display device (10) is a back projection display and the internal light source comprises a lamp tube or a light emitting diode.   The display device (10) of claim 1, wherein the display device (10) is a projection device and the internal light source comprises a lamp tube or a light emitting diode. A control module (82) for preventing harmonic interference in the display device (10),
The display device (10) receives an image signal (702) having a display scanning frequency, displays an image corresponding to the image signal (702),
The display device (10) includes an internal light source (9) and a light source adjustment module (8) electrically coupled to the internal light source (9), the light source adjustment module (8) being operable. A pulse width modulation controller (80) that can generate a source control signal (801) to control turn on and turn off of the internal light source (9),
The control module (82)
A frequency detection circuit (60) adapted to detect the display scanning frequency of the image signal (702);
A plurality of range adjustment circuits (61, 62, 63), each adapted to be electrically coupled to the frequency detection circuit (60) and electrically coupled to the pulse width modulation controller (80);
Have
The frequency circuit (60) activates one of the range adjustment circuits (61, 62, 63) according to the detected display scanning frequency,
Since the activated one of the range adjustment circuits (61, 62, 63) controls the pulse width modulation controller (80), the pulse width modulation controller (80) is connected to the range adjustment circuit (61). , 62, 63) corresponding to the activated one of the turn-on and turn-off frequencies that are not an integer multiple of the display scanning frequency detected by the frequency detection circuit (60). Generating the source control signal (801) within a frequency range;
Control module. Each of the range adjustment circuits (61, 62, 63) includes a ground switch (611, 621, 631) coupled and controlled by the frequency detection circuit (60), and the ground switch (611, 621, 631) and a capacitor (611, 621, 631) adapted to be coupled to the pulse width modulation controller (80) at the other end of the terminal;
The control module (82) of claim 7. A display device (10) adapted to receive an image signal (702) having a display scanning frequency and to display an image corresponding to the image signal (702),
An internal light source (9);
A pulse width modulation controller (80) that is electrically coupled to the internal light source (9) and is operable to generate a source control signal (801) to control turn-on and turn-off of the internal light source (9) A light source adjustment module (8);
A frequency detection circuit (60) for detecting the display scanning frequency of the image signal (702), and a plurality of the frequency detection circuit (60) and a plurality of pulse width modulation controllers (80) electrically coupled to the frequency detection circuit (60). A control module (82) including a switch circuit (61, 62, 63);
Have
The frequency detection circuit (60) operates one of the switch circuits (61, 62, 63) according to the detected display scanning frequency,
Since the activated one of the switch circuits (61, 62, 63) controls the pulse width modulation controller (80), the pulse width modulation controller (80) is connected to the switch circuit (61, 62). 63) and a preset frequency range having the turn-on and turn-off frequencies corresponding to the activated one of the display scan frequencies detected by the frequency detection circuit (60) and not an integer multiple of the display scan frequency. To generate the source control signal (801),
Display device. A control module (82) for preventing harmonic interference in the display device (10),
The display device (10) receives an image signal (702) having a display scanning frequency, displays an image corresponding to the image signal (702),
The display device (10) includes an internal light source (9) and a light source adjustment module (8) electrically coupled to the internal light source (9), the light source adjustment module (8) being operable. A pulse width modulation controller (80) that can generate a source control signal (801) to control turn on and turn off of the internal light source (9),
The control module (82)
A frequency detection circuit (60) adapted to detect the display scanning frequency of the image signal (702);
A plurality of switch circuits (61, 62, 63) each adapted to be electrically coupled to the frequency detection circuit (60) and electrically coupled to the pulse width modulation controller (80);
Have
The frequency circuit (60) activates one of the switch circuits (61, 62, 63) according to the detected display scanning frequency,
Since the activated one of the switch circuits (61, 62, 63) controls the pulse width modulation controller (80), the pulse width modulation controller (80) is connected to the switch circuit (61, 62). 63) and a preset frequency range having the turn-on and turn-off frequencies corresponding to the activated one of the display scan frequencies detected by the frequency detection circuit (60) and not an integer multiple of the display scan frequency. Generating the source control signal (801),
Control module.

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