JP3078497U - Image display device with on-screen display function when there is no signal - Google Patents

Abstract

(57) [Summary] [PROBLEMS] In a television receiver having an on-screen function when there is no signal, even if the electric field level of the image signal is low or noise is mixed in the signal, the signal can be accurately detected. Judge the presence or absence, and if there is no signal, indicate so. SOLUTION: An inverted flyback pulse corresponding to a horizontal synchronization frequency output from a chroma IC is counted (# 1).
1) The presence or absence of an image signal is determined based on whether or not the number of synchronization signals in one frame is 525 (# 2). If the number of the synchronization signals is not 525 (N in # 2)
O), this determination is further repeated 10 times (# 3), and if the number of synchronization signals is not all 525 (N in # 4)
O), it is determined that there is no image signal, and a predetermined display is performed on the OSD (# 5).

Description

[Detailed description of the invention]

[0001]

[Industrial applications]

 The present invention relates to an image display device that displays an on-screen (hereinafter, referred to as OSD) on a picture tube when an image signal is not received.

[0002]

[Prior art]

 2. Description of the Related Art Conventionally, there has been known an image display device such as a television receiver that determines an electric field intensity level of an input image signal and performs processing in accordance with the electric field intensity level. As an example, when the antenna input is a weak electric field, the screen display signal is output to the video output circuit through a circuit that limits the spurious band, and when the antenna level is medium or high, the screen display signal is directly output to the video output circuit. There is a screen display device provided with a changeover switch for outputting (for example, see Japanese Utility Model Laid-Open No. 63-52355). There is also a television receiver that sequentially selects a television broadcast wave and displays the electric field strength level of a receivable channel on a display. (See, for example, Japanese Patent Publication No. 5-25431). This is to make it possible to easily grasp the television reception status when the vehicle is mounted on a car or the like and moves.

When the electric field strength of a received signal is equal to or less than a predetermined value, or when it is determined that there is no received signal, a reference signal necessary for phase synchronization of image display is output from another oscillator. Some display characters using the supplied signal or using a free-run state (see, for example, JP-A-2-305185 and JP-A-2-205180). These are designed to provide stable and clear character display without causing jitter in character display and display at abnormal positions even when the reception state fluctuates.

Further, the number of synchronization signals per predetermined time is detected from the input synchronization signal, and when the predetermined number of synchronization signals are not detected, it is determined that there is no image signal, and a predetermined display is performed. (For example, see Japanese Patent No. 2679054).

[0005]

[Problems to be solved by the invention]

 Television receivers are required to display such information on display means such as an LED or OSD when the switch of the receiver is on and there is no image signal during a black raster screen, that is, when there is no image signal. Therefore, a television receiver requires a device for detecting the presence or absence of an image signal. In the television receivers disclosed in Japanese Utility Model Application Laid-Open No. 63-52355, Japanese Patent Publication No. 5-25431, Japanese Patent Application Laid-Open No. 2-305185, and Japanese Patent Application Laid-Open No. 2-205180, the electric field intensity level of an image signal is controlled. It detects it and performs subsequent processing based on its intensity level. Therefore, it is possible to determine the presence or absence of an image signal based on whether the electric field strength level is larger or smaller than a predetermined threshold value. However, such a determination method makes it difficult to accurately detect the intensity level when the electric field level of the image signal is low or when noise is mixed in the image signal.

Further, in the television receiver disclosed in Japanese Patent No. 2679054, the presence or absence of an image signal is determined based on the number of synchronization signals as described above. Since the reception state is determined by detecting the number, accurate detection is also difficult when the electric field is weak or when noise is mixed in the synchronization signal.

The present invention has been made to solve the above-described problem, and accurately determines the reception state even when the electric field level of a signal is low or when noise is mixed in the signal. Another object of the present invention is to provide a television receiver which can display a signal when there is no signal.

[0008]

[Means for Solving the Problems]

 In order to achieve the above object, the invention of claim 1 comprises a display means for displaying an image, and a flywheel for boosting a horizontal drive pulse applied to the display means at a frequency corresponding to a horizontal synchronization signal for displaying the image. A back transformer and display command means for displaying a predetermined on-screen display (hereinafter referred to as OSD) by outputting a command to the display means, and the horizontal synchronizing signal is used when an image signal is not input. An image display device having an on-screen display function when there is no signal, in which a predetermined free-run frequency is achieved, and when an image signal is input, the image is displayed by tuning to the horizontal synchronization frequency of the image signal. Pulse inverting means for inverting a flyback pulse fed back from a flyback transformer, and a pulse inverted by the pulse inverting means. Pulse counting means for counting back pulses, wherein the pulse counting means repeatedly counts the number of inverted flyback pulses included in the time for outputting one frame of the image, and calculates the number of inverted flyback pulses and If the horizontal synchronization frequency (15.734 kHz) divided by the number of frames displayed per second (30) (525) does not match, the display command means determines that the camera is in a free-run state with no image signal. This determination is repeated a predetermined number of times, and when it is determined in all the determinations that the vehicle is in the free-run state, a command to display a predetermined OSD is output to the display means.

In this configuration, the pulse counting means counts the inverted flyback pulse signal for one frame of the image. The flyback pulse returned from the flyback transformer is normally a high voltage of about 100 V, but is inverted by a pulse inversion means and is lowered to about 5 V. In the present invention, since the inverted flyback pulse is detected, a high-voltage pulse signal is not applied to the pulse counting means, so that an element such as a microcomputer can be applied. If the count value counted by the pulse counting means does not match the number (525) obtained by dividing the horizontal synchronization frequency (15.734 kHz) by the number of frames displayed per second (30), The display means is in the free-run state, and it is determined that there is no image signal.

Here, when the image signal is a weak electric field, the DC voltage of the synchronization signal of the inverted flyback pulse is also small, and if noise is mixed in this synchronization signal, it may be difficult to accurately count the number of pulses. is there. In contrast, in the present invention, the number of pulses is repeatedly counted and determined. That is, the presence / absence of an image signal is not determined from one detection result, but is performed based on the result of counting a predetermined number of times. Therefore, the presence / absence of an image signal can be accurately determined.

The invention of claim 2 provides a display device for displaying an image, a signal detection device for detecting a horizontal synchronization signal for displaying an image, and a command to the display device for outputting a predetermined command. In an image display device having display command means for displaying an on-screen display (hereinafter referred to as OSD), and having an on-screen display function when there is no signal, the signal detection means is capable of freeing the frequency of the detected horizontal synchronization signal. The change with respect to the run frequency is monitored, and if the change in the frequency occurs a predetermined number of times or more within a predetermined time, the display command means determines that it is in a free-run state where there is no image signal. This is for outputting a command for performing a predetermined OSD display. In this configuration, the detection of the horizontal synchronizing signal is not limited to the detection based on the detection of the inverted flyback pulse signal. Then, the signal detecting means determines that there is no image signal when the frequency of the horizontal synchronizing signal has changed a predetermined number of times or more within a predetermined time.

Further, the invention according to claim 3 is a display means for displaying an image, and an automatic gain adjustment (hereinafter, referred to as AGC) for automatically adjusting a luminance gain according to a luminance level of a reproduced image signal of a video tape. An image processing circuit which incorporates a circuit and processes a luminance signal supplied to the display means; and a display command means for outputting a command to the display means to display a predetermined on-screen display (hereinafter referred to as OSD). In an image display device having an on-screen display function when there is no signal, the display command means detects the voltage of the AGC voltage detection terminal of the image processing circuit, and when this voltage reaches the voltage level when there is no signal, This is to output a display command to determine that there is no image signal and to cause the display means to perform a predetermined OSD display. In this configuration, the display command means detects a signal corresponding to the luminance level of the reproduced image of the video tape from the AGC voltage detection terminal, and determines the presence or absence of an image signal based on the voltage level. When there is no signal of the reproduced image of the video tape, the voltage of the AGC voltage detection terminal rises because the AGC circuit performs processing for increasing the luminance gain. Therefore, if the voltage of the AGC voltage detection terminal is equal to or higher than the predetermined set value, it can be determined that there is no signal of a reproduced image of the video tape. Since there is almost no noise in the signal detected by the AGC voltage detection terminal, the presence or absence of an image signal can be accurately determined.

According to a fourth aspect of the present invention, there is provided a display means for displaying an image, and an automatic gain adjustment (hereinafter referred to as AGC) circuit for automatically adjusting a luminance gain according to a luminance level of an image signal. An image processing circuit for processing a luminance signal supplied to the display means, and display command means for outputting a command to the display means to display a predetermined on-screen display (hereinafter referred to as OSD); In an image display device having an on-screen display function, the display command means detects the voltage of the AGC voltage detection terminal of the image processing circuit, and when this voltage is higher than a predetermined value, determines that there is no image signal and displays. It outputs a display command for causing the means to perform a predetermined OSD display. In this configuration, the detection of the luminance level of the image signal is not limited to the reproduction signal from the video tape. Therefore, a signal corresponding to the brightness level of an image signal reproduced from another recording medium such as a DVD may be detected.

[0014]

[Embodiment of the invention]

 Embodiment 1 Hereinafter, a television receiver according to one embodiment of the invention will be described with reference to the drawings. FIG. 1 shows a configuration of a television receiver. The television receiver 10 includes an electron gun, a CRT 1 for displaying an image by an electron beam emitted from the electron gun, a flyback transformer 2 for applying a voltage to the electron gun of the CRT 1, and a color (RGB) for the CRT 1. It comprises a chroma IC 3 for transmitting signals and a microcomputer (display command means, pulse counting means) 4 for controlling the whole of the television receiver 10. The display means is constituted by the CRT 1 and the chroma IC 3.

The CRT 1 uses the voltage applied by the flyback transformer 2 based on the synchronization signal and the color signal transmitted from the chroma IC 3 to direct the electron beam from the electron gun toward a desired position on the phosphor screen. The light is emitted to form an image. The flyback transformer 2 applies the boosted voltage to the CRT 1 and feeds back the flyback pulse 2 to the chroma IC 3. As described above, the chroma IC 3 receives the color signal from the microcomputer 4, transmits the color signal to the CRT 1, and lowers and inverts the flyback pulse from the flyback transformer 2, The inverted flyback pulse is transmitted to the microcomputer 4.

The flyback transformer 2 of the television receiver 10 operates at a predetermined free-run frequency when not receiving an image signal of 15.734 kHz, which is a horizontal synchronization frequency of television broadcasting, and receives the image signal. When this is done, the operating frequency is pulled down to the above frequency (15.734 kHz) for tuning. Therefore, since the horizontal synchronizing frequency fluctuates between when the image signal is not received and when the image signal is received, the presence or absence of the image signal can be determined by monitoring the fluctuation of the horizontal synchronizing frequency.

When the television receiver 10 receives an image signal, the flyback pulse fed back from the flyback transformer 2 is a pulse signal corresponding to the horizontal motive frequency of the image signal as P1 and P2 in FIG. , P3,..., Pn. In television broadcasting of the NTSC (National Television System Committee) standard, as described above, the horizontal synchronization frequency is 15.734 kHz, and pulses corresponding to 30 frames per second are generated. Therefore, the number n of pulses per frame is a value obtained by dividing the horizontal synchronization frequency by the number of frames displayed per second, that is, 525. On the other hand, the inverted flyback pulse is obtained by inverting the flyback pulse, and is represented by the waveforms indicated by Q1, Q2, Q3,..., Qn in FIG. Is the same as the flyback pulse, and is 525. Therefore, when the number n of inverted flyback pulses per frame counted (counted down) by the microcomputer is 525, the television receiver 10 is determined to be receiving a television broadcast, and the above-mentioned one frame is determined. When the number of pulses per hit n is not 525, it is determined that the television broadcast is not received, that is, there is no image signal in the free-run state. Normally, the peak voltage of the flyback pulse is about 100 V, but the peak voltage of the inverted flyback pulse is reduced to -5 V, so that the pulse can be detected within the allowable voltage of the microcomputer 4.

In the present invention, the number n of inverted flyback pulses per frame is repeatedly counted, and the microcomputer 4 counts the flyback pulses continuously for a predetermined number of times to make a determination. I have. Therefore, the presence or absence of an image signal of the television receiver 10 can be accurately determined.

As a result of the above determination, when it is determined that there is no image signal, the microcomputer 4 causes the CRT 1 to output a predetermined OSD display via the chroma IC 3. The OSD display is performed by displaying, for example, characters such as “video” and “AV” on the CRT 1. Further, instead of the OSD display, the display may be performed by an LED (light emitting diode) provided separately.

Next, a processing procedure of the microcomputer 4 in the television receiver 10 will be described with reference to FIG. The microcomputer 4 counts down the inverted flyback pulse of the horizontal synchronization signal transmitted from the chroma IC 3 for one frame (# 1), and when the number n of the synchronization signals during the one frame is not 525 (at # 2). In the case of (NO), this determination is repeated ten times (# 3). If all of the ten confirmations are not 525 (NO in # 4), a predetermined OSD display is performed (# 5). If the number n of synchronization signals is 525 (YES in # 2 and # 4), the process returns to # 1 without performing OSD display (# 6).

Embodiment 2 FIG. 4 shows a configuration of a television receiver according to another embodiment that embodies the present invention. The television receiver 20 has a recording / reproducing function of a video tape, and has the same CRT 1, chroma IC 3, microcomputer 4, and luminance, chroma and audio as the television receiver 10 of the first embodiment. YCA (Y: brightness signal, C: chroma, A: audio) IC (image processing circuit) 21 for processing signals, a head cylinder 22 for recording / reproducing a loaded video tape, and a video input terminal 23 , A tuner 24, an antenna 24a, and a video output terminal 25.

The YCA IC 21 has a built-in AGC circuit 21a. The AGC circuit 21a is a circuit that automatically adjusts the gain of a signal according to the intensity level of an image signal and always obtains a signal of a constant level. An AGC voltage detection terminal (port) 21b of the AGC circuit 21a has an AGC voltage detection terminal (port) 21b for detecting an image displayed on the CRT 1 when the luminance level of an image signal input from the head cylinder 22, the video input terminal 23 or the tuner 24 changes. A capacitor 26 and a resistor 27 for adjusting the luminance response are connected.

The voltage at the AGC voltage detection terminal 21b fluctuates due to the operation of the AGC circuit 21a. Specifically, when there is no image signal, a process for increasing the luminance gain is performed in the AGC circuit 21a, so that the voltage of the AGC voltage detection terminal 21b increases. Conversely, when there is an image signal and a sufficient luminance level is maintained, the voltage of the AGC voltage detection terminal 21b falls. In the present invention, the microcomputer 4 detects the thus-varying voltage level of the AGC voltage detection terminal 21b to determine the presence or absence of an image signal. If necessary, the result is displayed by OSD. That is, when the voltage of the AGC voltage detection terminal 21b reaches a voltage level corresponding to the absence of a signal, it is determined that there is no image signal, and the CRT 1 is instructed to perform a predetermined OSD display. On the other hand, when the voltage level is not reached, it is determined that there is an image signal, and the OSD display is not performed. Since the signal detected by the AGC voltage detection terminal 21b hardly contains noise, the presence or absence of an image signal can be accurately determined.

Next, a processing procedure of the microcomputer 4 in the television receiver 20 will be described with reference to FIG. The microcomputer 4 checks the voltage of the AGC voltage detection terminal 21b of the YCA IC 5 (# 11). If the voltage of the AGC voltage detection terminal 21b is equal to or higher than the set voltage (YES in # 12), a predetermined OSD is output to the CRT1. Display is performed (# 13). On the other hand, if the voltage of the AGC voltage detection terminal 21b is not equal to or higher than the set voltage (NO in # 12), the OSD display is not performed (# 14), and the process returns to # 11.

The present invention can be variously modified without being limited to the configuration of the above embodiment. For example, the number of repetitions indicated by # 3 in FIG. 3 of the first embodiment is limited to 10 times. Alternatively, the number of times may be less than 10 if the number is sufficient for accurate determination, and may be more than 10 if strict determination is desired. Further, the determination of the synchronization signal in # 2 and # 4 may be made based on "is the number of signals corresponding to a predetermined free-run frequency?"

The television receiver 20 according to the second embodiment is not limited to the one having the function of reproducing a video tape, and may be applied to the one having the function of recording / reproducing a recording medium such as a DVD. Good.

Further, the embodiment to which the present invention is applied is not limited to the television receivers 10 and 20, and can be applied to other image display devices. The image displayed on the image display device may be a still image or a moving image.

[0028]

[Effect of the invention]

 As described above, according to the invention of claim 1, the number of pulses is repeatedly detected, and the presence or absence of an image signal is determined based on the detection result of the predetermined number of times. Therefore, when the image signal is a weak electric field, Even when noise is mixed in the signal, the presence or absence of an image signal can be accurately determined and output from the display means to notify the user. Also, if the microcomputer used for the display command means is also used as the pulse counting means, low-cost response can be achieved by changing the microcomputer software without adding new parts.

According to the invention of claim 2, the same effect as that of claim 1 can be obtained even when the image displayed by the display means is a still image.

According to the invention of claim 3, since the presence or absence of an image signal is determined based on the voltage level of the AGC voltage detection terminal, the presence or absence of the image signal is accurately determined, output from the display means, and provided to the user. Can be informed. Further, if the AGC voltage is detected by the microcomputer used as the display command means, low-cost measures can be taken by changing the microcomputer software without adding new parts.

According to the present invention, the presence or absence of an image signal from a recording medium such as a DVD can be determined.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a television receiver according to an embodiment of the present invention.

FIG. 2 is a view showing a waveform of a horizontal synchronization signal per frame of an image displayed by the receiver.

FIG. 3 is a flowchart showing a processing procedure of a microcomputer of the receiver.

FIG. 4 is a block diagram of a television receiver according to another embodiment of the present invention.

FIG. 5 is an exemplary flowchart showing a processing procedure of a microcomputer of the receiver.

[Explanation of symbols]

 Reference Signs List 1 CRT (display means) 2 Flyback transformer 3 Chroma IC (display means, pulse detection means) 4 Microcomputer (display command means, pulse detection means) 10, 20 Television receiver 21 YCA IC (image processing circuit) 21a Automatic gain adjustment circuit 21b AGC voltage detection terminal

Claims (4)

[Utility model registration claims] A display means for displaying an image; a flyback transformer for boosting a horizontal drive pulse applied to the display means at a frequency corresponding to a horizontal synchronization signal for displaying the image; By outputting a command, a predetermined on-screen display (hereinafter referred to as OS
D) display command means for performing display. The horizontal synchronizing signal has a predetermined free-run frequency when no image signal is input, and the horizontal synchronizing frequency of the image signal when an image signal is input. In an image display apparatus for displaying an image by tuning to, a pulse inverting means for inverting a flyback pulse fed back from the flyback transformer, and a pulse counting means for counting the flyback pulse inverted by the pulse inverting means The pulse counting means repeatedly counts the number of inverted flyback pulses included in the time for outputting one frame of the image, and counts the number of inverted flyback pulses and the horizontal synchronization frequency (15. 734 kHz) divided by the number of frames displayed per second (30) (525) When the display command means determines that it is in the free-run state where there is no image signal, and repeats this determination a predetermined number of times. Predetermined OSD for
An image display device having an on-screen display function when there is no signal, which outputs a command to display. 2. A display device for displaying an image, a signal detection device for detecting a horizontal synchronization signal for displaying the image, and a predetermined on-screen display (hereinafter, referred to as a display device) by outputting a command to the display device. , OSD), a display commanding means for performing display. The signal detecting means monitors a fluctuation of a frequency of the detected horizontal synchronizing signal with respect to a free-run frequency. When a predetermined number of occurrences occur within a period of time, the display command means determines that the vehicle is in a free-run state with no image signal, and outputs a command to display a predetermined OSD to the display means. An image display device having an on-screen display function when there is no signal. 3. A built-in display means for displaying an image and an automatic gain adjustment (hereinafter referred to as AGC) circuit for automatically adjusting a luminance gain in accordance with a luminance level of a reproduced image signal of a video tape, wherein the display means is provided. An image display device comprising: an image processing circuit that processes a supplied luminance signal; and a display command unit that outputs a command to the display unit to display a predetermined on-screen display (hereinafter, referred to as OSD). The display command means detects a voltage at an AGC voltage detection terminal of the image processing circuit, and when this voltage reaches a voltage level when there is no signal, judges that there is no image signal and gives a predetermined signal to the display means. An image display device having an on-screen display function when there is no signal, which outputs a display command for OSD display. 4. A built-in display means for displaying an image and an automatic gain adjustment (hereinafter referred to as AGC) circuit for automatically adjusting a luminance gain according to a luminance level of an image signal, and a luminance signal supplied to the display means. An image display device comprising: an image processing circuit that processes the image data; and a display command unit that outputs a command to the display unit to display a predetermined on-screen display (hereinafter, referred to as an OSD). Detecting a voltage of an AGC voltage detection terminal of the image processing circuit, and when the voltage is higher than a predetermined value, determining that there is no image signal and outputting a display command for displaying a predetermined OSD to the display means. An image display device having an on-screen display function when there is no signal.