DE102005015847A1 - Single frequency multi mode display unit e.g. high resolution television screen, has control unit, which scales original picture content, where electron beam of gun scans screen so that image is represented on screen with preset resolution - Google Patents

Abstract

The unit has a control unit (36), which scales an original picture content to a preset resolution to maintain a scaled picture content. A horizontal deflection circuit (31) and a vertical deflection circuit are driven using horizontal and vertical deflection signals output from the control unit. The electron beam of the electron gun scans the display screen so that the image is represented on the screen with a predetermined resolution.

Description

The The present invention relates to a single frequency analog multimode analog display unit and in particular to an analogue display unit which is an analogue display unit or digital display signal for various Accepted display modes and a scaling of the received in the Perform display signal contained image content to a predetermined resolution and Distracting signals can influence to optimal scanning realize.

graphics Cards for computer systems have starting from their ability to a single display mode (that is, a single resolution like 640 × 480 Pixels), modified to the extent that they are able are to generate multiple modes, such as 800 × 600, 1024 × 768 and 1280 × 1024 Pixels. Therefore needed a conventional cathode ray tube (CRT) is a circuit that allows, a picture content of different operating modes of graphics cards to receive and present (on a screen of the CRT).

A Conventional multi-frequency multimode CRT includes a video array (VGA) connection, which receives an analogue indication signal from a graphics card. The VGA connection outputs a horizontal synchronization signal to a microprocessor (Hsync) and a vertical synchronization signal (Vsync), the in the display signal and transmits to a preamplifier / on-screen display (OSD) generator circuit a picture content included in the display signal.

The Preamplifier / OSD generator circuit reinforced the image content and puts an OSD screen in the image content after receiving a corresponding instruction from the microprocessor has been. The preamp / OSD generator circuit then outputs the resulting signal to a power amplifier, for another reinforcement to undergo. The amplifier signal is issued to an electron gun.

simultaneously with the foregoing, the microprocessor outputs the horizontal synchronization signal (Hsync) and the vertical synchronization signal (Vsync) to a deflection controller that corresponds to the horizontal synchronization signal (Hsync) generates different control parameters and these a horizontal driver, a horizontal screen adjustment, a horizontal deflection voltage adjustment circuit and a CS circuit. The horizontal driver generates a horizontal deflection signal and inputs this signal to a power amplifier. The horizontal screen adjustment leads one Adjustment of the screen horizontal direction and its peripheral linearity on the basis of the horizontal deflection signal. The adjustment circuit for the Horizontal deflection voltage generates a control signal by a frequency setting perform, then outputs the control signal to a horizontal deflection circuit (Coil) to feed them. As a result, a horizontal scanning signal generated to the horizontal deflection of one of the electron gun To realize emitted electron beam. The CS circuit is connected to the horizontal deflection circuit and provides the horizontal scanning signal in accordance with the display signal of different operating modes, causing a compensation with respect to the screen in non-linear Manner performed becomes.

Furthermore The deflection control generates a vertical deflection signal corresponding to the vertical synchronization signal (Vsync) and sends the generated vertical deflection signal to one Power amplifier. The power amplifier amplifies that Vertical deflection signal then outputs the resulting signal to a vertical deflection circuit (Coil) to feed them. As a result, a vertical scanning signal becomes generated to the vertical deflection of the electron gun To realize emitted electron beam. Consequently, the leads Electron gun scanning and output of the image content corresponding to the horizontal synchronization signal (Hsync) and the Vertical synchronization signal (Vsnyc) of the input display signal by.

Further work with the horizontal and vertical deflection circuits a linear control coil (not shown) together and correspond by a variation of their inductances different horizontal and vertical synchronization signal frequencies.

Therefore, when changes occur in the display mode of the inputted indication signal, for example, a change from a resolution of 640 × 480 pixels to 800 × 600 pixels, it is necessary that a corresponding increase in vertical sync signal and horizontal sync signal (eg, an increase of 60Hz to 70Hz or from 31kHz to 38kHz). In this case, the deflection controller must control the horizontal driver so as to adjust the frequency of the horizontal deflection signal properly, and further control the horizontal screen aperture such that width (as the horizontal synchronization frequency is increased, the display screen narrows) and peripheral linearity of the image displayed on the display screen be set. The deflection control also controls the horizontal deflection voltage setting circuit and the CS circuit to set the voltage level of the horizontal deflection signal (since the energy consumption of the horizontal deflection circuit may increase with frequency) as well as its linearity (since the horizontal direction). Deflection signal has non-linear properties). As a result, the power amplifier may generate a corresponding horizontal deflection signal according to different resolutions to control the horizontal deflection circuit to allow different resolutions to be displayed on the screen.

Around however, such an indication of different resolutions too enable, the conventional analog display includes the horizontal screen adjustment, the setting circuit for the horizontal deflection voltage and the CS circuit as well as circuits, e.g. linear Control coils for controlling the inductance levels of horizontal and Vertical deflection circuits. Consequently, not only will a considerable Amount of energy as a result of the large number of participants involved Elements consumed, but it must also during the production of the ad significant costs, time and effort in setting and testing be plugged to optimum conditions for each of the display modes to realize what ultimately leads to increased production costs.

task The invention therefore is an analogue single frequency multimode display unit to create that is capable of both analog and digital To accept display signals of different display modes and a scaling of the image content included in the received indication signal is at a predetermined resolution as well as influencing the deflection signals for realization to perform an optimal sampling.

The single frequency multimode display unit includes:
a display screen; an electron gun for emitting an electron beam toward the display screen; a horizontal deflection circuit and a vertical deflection circuit for controlling the deflection of the electron beam emitted from the electron gun; a single-frequency control unit for receiving an indication signal including an original image content, a horizontal synchronization signal and a vertical synchronization signal; and a deflection control unit coupled to the single frequency control unit, the horizontal deflection circuit and the vertical deflection circuit.

• (a) skaliert den ursprünglichen Bildinhalt auf eine vorbestimmte Auflösung, um dadurch einen skalierten Bildinhalt zu erhalten; und gibt den skalierten Bildinhalt an die Elektronenkanone aus,
• (b) ersetzt das Horizontal-Synchronisationssignal des Anzeigesignals durch ein festes Horizontal-Synchronisationssignal, und
• (c) gibt das feste Horizontal-Synchronisationssignal und das Vertikal-Synchronisationssignal des Anzeigesignals aus.

The single-frequency control unit

• (a) scales the original image content to a predetermined resolution to thereby obtain a scaled image content; and outputs the scaled image content to the electron gun,
• (b) replaces the horizontal synchronizing signal of the display signal with a fixed horizontal synchronizing signal, and
• (c) outputs the fixed horizontal synchronizing signal and the vertical synchronizing signal of the indicating signal.

The The deflection control unit generates at the same time as the output of the Electron beam from the electron gun a horizontal deflection signal and a vertical deflection signal respectively corresponding to the fixed horizontal synchronization signal and the vertical synchronization signal of the single-frequency control unit equivalent. The horizontal deflection signal and the vertical deflection signal drive respectively the horizontal deflection circuit and the vertical deflection circuit so that the electron beam the electron gun scans the display screen so that the images be displayed on it with the predetermined resolution.

Further Features and advantages of the present invention will become apparent from the following detailed description of the preferred embodiment with reference to the accompanying drawings clear.

It demonstrate:

1 FIG. 4 is a block diagram of a single-frequency analog multimode display unit according to a preferred embodiment of the present invention and FIG.

2 a detailed block diagram of a single-frequency control 1 ,

With reference to 1 can be a single-frequency analog multimode display unit 3 According to a preferred embodiment of the present invention, a cathode ray tube (CRT) or a high definition television screen (HDTV) capable of displaying analog signals. It is assumed that, for purposes of description, the analog display unit 3 the preferred embodiment is a CRT.

The single-frequency multimode display unit 3 includes a display (not shown) screen, an electron gun 30 , a horizontal deflection circuit 31 , a vertical deflection circuit 32 , a Videographic Assembly (VGA) connector 33 , a Digital Video Interface (DVI) connector 34 , a multiplexer 35 , a single-frequency control unit 36 , a distraction control unit 37 , a first power amplifier 38 , a second power amplifier 39 , a third power amplifier 40 and a microprocessor 41 ,

The electron gun 30 emits an electron beam toward the display screen to excite phosphor particles deposited on the inner surface of the display screen in a coating. The horizontal deflection circuit 31 and the vertical deflection circuit 32 control the distraction of the electron gun 30 emitted electron beam so that the electron beam scans the display screen, thereby realizing the display of the image on the screen. A preparation of each to the electron gun 30 , the horizontal deflection circuit 31 and the vertical deflection circuit 32 supplied signals for performing such a scanning of the display screen by the electron beam is described below: The VGA connector 33 and the DVI connector 34 are coupled to the graphics card of a computer (not shown) to receive signals. That is, the VGA connector 33 a first analogue indication signal and the DVI connector 34 receiving both a second analogue indication signal and a digital indication signal. Each of the first and second analog display signals, as well as the digital display signal, includes the image content (that is, gray-scale information), a horizontal sync signal (Hsync), and a vertical sync signal (Vsync). The VGA connector 33 is with the multiplexer 35 coupled to output to this the first analog display signal. The DVI connector 33 is with the multiplexer 35 coupled to output the first analogue indication signal thereto. The DVI connector 34 includes an analog output port 341 that with the multiplexer 35 is coupled to output to this second analogue display signal, and a digital output terminal 342 that with the single-frequency control unit 35 is coupled to output to this the digital display signal.

The multiplexer 35 may operate to receive a signal from the first analogue indication signal from the VGA connector 33 and the second analogue indication signal from the analogue output terminal 341 of the DVI connector 34 selected. The multiplexer 35 includes an output port 351 that with the single-frequency control unit 36 is coupled. The multiplexer 35 outputs the signal selected from the first and second analog display signals to the single-frequency control unit 36 via the output connector 351 from.

With reference to 2 includes the single-frequency control unit 36 a fixed frequency generator 360 , an analog-to-digital converter (ADC) 361 , a scaler 362 , a digital-to-analog converter (DAC) 363 , a preamp 364 and an OSD generator circuit 365 ,

The fixed frequency generator 360 receives the horizontal sync signal (Hsync) and the vertical sync signal (Vsync) of the selected analogue indication signal and generates a fixed horizontal sync signal (Fix-Hsync), such as a 90kHz signal. The fixed frequency generator 360 substitutes the horizontal synchronizing signal (Hsync) of the selected analogue display signal with the fixed horizontal synchronizing signal (Fix-Hsync) while leaving the vertical synchronizing signal (Vsync) unchanged. The fixed frequency generator 360 outputs the fixed horizontal sync signal (Fix-Hsync) and the vertical sync signal (Vsync) to the deflection control unit 37 from.

The ADC 361 is with the multiplexer 35 and acts to convert the image content contained in the received selected analogue indication signal into digital form to obtain an image content, hereinafter referred to as "original image content." The ADC 361 sends the original image content to the scaler 362 , The scaler 362 is also connected to the digital output port 342 of the DVI connector 34 coupled. When the display signal is digital, the image content contained in the digital display signal is directly used as the original image content.

The scaler 362 Scaling the original image content results in a scaled image content of a predetermined resolution. That is, the original image content has inherent resolution and the scaler 362 the original image content is scaled based on the inherent resolution of the original image content. The scaler 362 performs scaling using conventional up-conversion and down-conversion techniques employing interpolation. Since these scaling processes are conventional, no detailed description needs to be given for this.

The scaled image content is scanned by the scaler 362 in the DAC 363 entered. The DAC 363 converts the data into analog form, thereby obtaining an analog-converted image content. The DAC 363 gives the analog-converted image content to the preamplifier 364 out, the ana log-konver reinforced image content to obtain a pre-amplified image content. The preamp 364 then outputs the pre-amplified image content to the first power amplifier 38 which performs the amplification of the pre-amplified image content and then the resulting image content to the electron gun 30 outputs.

The OSD generator circuit 365 the single-frequency control unit 36 is with the preamp 364 coupled and operates in accordance with those of the microprocessor 41 (please refer 1 ) received instructions. This means that after receiving an instruction from the microprocessor 41 the OSD generator circuit 365 insert an OSD screen into the analog-converted image content of the preamp 364 is processed so that the OSD screen in the of the electron gun 30 received image content is included. Consequently, user control is provided for image options and / or the adjustment of components of the display unit.

The distraction control unit 37 generates a horizontal deflection signal and a vertical deflection signal respectively corresponding to the fixed horizontal synchronization signal (Fix-Hsync) and the vertical synchronization signal (Vsync). The horizontal deflection signal and the vertical deflection signal are applied to the second power amplifier, respectively 39 and the third power amplifier 40 output so that they are subjected to amplification. The amplified signals are used for the horizontal deflection circuit 31 and the vertical deflection circuit 32 to drive so that the electron beam of the electron gun 30 scans the display screen so that images are displayed thereon in the predetermined resolution.

In the present invention as described above, the scaler is 362 the single-frequency control unit 36 capable of scaling the image content received from the graphics card with an inherent resolution to a predetermined resolution. Furthermore, the single frequency control unit performs 36 control such that the fixed horizontal synchronization signal (Fix-Hsync) replaces the existing horizontal synchronization signal. The fixed horizontal sync signal (Fix-Hsync) and the existing vertical sync signal (Vsync) are used to deflect and sample the electron gun 30 to control emitted electron beam. As a result, the resolution of the image content appearing on the screen remains constant.

at The above-described configuration of the invention are various Elements as found in a conventional CRT are also omitted like the horizontal screen adjustment, the setting circuit for the Horizontal deflection voltage, the CS circuit and the control coil. this leads to to a simpler overall construction and consequently lower Production costs and to a lower energy consumption.

Further, since the horizontal synchronizing signal is set to a single frequency, mode setting and measuring operations are made easy. Consequently, it is possible to realize an optimal display by a single resolution setting, thereby improving reliability and production efficiency. In addition, the circuit of the deflection control unit 37 be simplified because the horizontal synchronization signal is not varied.

Claims (8)

Single-frequency multimode display unit ( 3 ), characterized by - a display screen; An electron gun ( 30 ) for emitting an electron beam toward the display screen; A horizontal deflection circuit ( 31 ) and a vertical deflection circuit ( 32 ) for controlling the deflection of the electron beam emitted from the electron gun; A single-frequency control unit ( 36 ) for receiving an indication signal comprising an original image content, a horizontal synchronization signal and a vertical synchronization signal; wherein the single-frequency control unit ( 36 ) (a) scales the original image content to a predetermined resolution to thereby obtain a scaled image content; and outputting the scaled image content to the electron gun, (b) replacing the horizontal synchronizing signal of the display signal with a fixed horizontal synchronizing signal, and (c) outputting the fixed horizontal synchronizing signal and the vertical synchronizing signal of the indicating signal, and a deflection control unit having the single-frequency control unit ( 36 ), the horizontal deflection circuit ( 31 ) and the vertical deflection circuit ( 32 ), the distraction control unit ( 37 ) simultaneously with the output of the electron beam from the electron gun ( 30 ) generates a horizontal deflection signal and a vertical deflection signal respectively corresponding to the fixed horizontal synchronization signal and the vertical synchronization signal of the single frequency control unit ( 36 ), wherein the horizontal deflection signal and the vertical deflection signal respectively the horizontal deflection circuit ( 31 ) and the vertical deflection circuit ( 32 ) so that the electric beam of the electron gun ( 30 ) scans the display screen so that the images are displayed thereon at the predetermined resolution. Single-frequency multimode display unit ( 3 ) according to claim 1, characterized in that the single-frequency control unit ( 36 ) comprises: a fixed frequency generator ( 360 ) for receiving the horizontal synchronizing signal and the vertical synchronizing signal of the display signal and outputting the predetermined horizontal synchronizing signal and the vertical synchronizing signal; - a scaler ( 362 ) for scaling the original image content to result in the scaled image content of the predetermined resolution; and a digital-to-analog converter (DAC) ( 363 ), with the scaler ( 362 ), the DAC ( 363 ) performs an analog conversion of the scaled image content to thereby obtain an analog-converted image content. Single-frequency multimode display unit ( 3 ) according to claim 2, characterized in that the single-frequency control unit ( 36 ) further comprises: - an analog-to-digital converter (ADC) ( 361 ), with the scaler ( 362 ) in order to perform a digital conversion of an analog display signal to thereby obtain the original image content which is sent to the scaler ( 362 ) is output. Single frequency multimode display unit ( 3 ) according to claim 3, characterized in that the original image content of the display signal has an inherent resolution, wherein the scaler ( 362 ) scales the original image content based on the inherent resolution of the original image content. Single-frequency multimode display unit ( 3 ) according to claim 2, characterized in that the single-frequency control unit ( 36 ) further comprises: - a preamplifier ( 364 ) with the DAC ( 363 ) is coupled to receive the analog-converted image content; and a generator circuit ( 365 ) for an on-screen display (OSD) connected to the preamplifier ( 364 ) is coupled. Single-frequency multimode display unit ( 3 ) according to claim 5, further characterized by: - a first power amplifier ( 38 ) between the electron gun ( 30 ) and the preamplifier ( 364 ) of the single-frequency control unit ( 36 ), the first power amplifier ( 38 ) a gain of the preamplifier ( 364 ) performs pre-amplified image content and the resulting image content to the electron gun ( 30 ) outputs; A second power amplifier ( 39 ) located between the diversion control unit ( 37 ) and the horizontal deflection circuit ( 31 ), the second power amplifier ( 39 ) amplification of the fixed horizontal deflection signal from the deflection control unit (FIG. 37 ) and the resulting horizontal deflection signal to the horizontal deflection circuit ( 31 ) outputs; and - a third power amplifier ( 40 ) located between the diversion control unit ( 37 ) and the vertical deflection circuit ( 32 ), the third power amplifier ( 40 ) amplification of the vertical deflection signal from the vertical control unit ( 37 ) and the resulting vertical deflection signal to the vertical deflection circuit ( 32 ). Single-frequency multimode display unit ( 3 ) according to claim 3, further characterized by: - a video graphics array (VGA) connector ( 33 ) for receiving a first analogue indication signal; A digital video interface (DVI) connector ( 34 ), which has an analogue output terminal ( 341 ) and a digital output terminal ( 342 ), wherein the DVI connector ( 34 ) receives a second analogue indication signal which is output via the analogue output port ( 341 ), the DVI connector ( 34 ) further receives a digital display signal which is sent to the scaler via the digital output port ( 342 ) is output; and - a multiplexer ( 35 ) with the ADC ( 361 ), the VGA connector ( 33 ) and the analogue output terminal ( 341 ) of the DVI connector ( 34 ), the multiplexer ( 35 ) is operable to receive the first analogue indication signal from the VGA connector ( 33 ) or the second analogue indication signal from the analogue output terminal ( 341 ) of the DVI connector ( 34 ) and selects the signal selected from the first and second analogue indication signals to the ADC ( 361 ). Single-frequency multimode display unit ( 3 ) according to claim 1, further characterized by: - a video graphics array (VGA) connector ( 33 ) for receiving a first analogue indication signal; A digital video interface (DVI) connector ( 34 ), which has an analogue output terminal ( 341 ) and a digital output terminal ( 342 ), wherein the DVI connector ( 34 ) receives a second analogue indication signal which is output via the analogue output port ( 341 ), the DVI connector ( 34 ) further receives a digital indication signal which is sent to the single-frequency control unit ( 36 ) via the digital output terminal ( 342 ) is output; and - a multiplexer ( 35 ), who with the Einzelfre frequency control unit ( 36 ), the VGA connector ( 33 ) and the analogue output terminal ( 341 ) of the DVI connector ( 34 ), the multiplexer ( 35 ) is operable to receive a signal from the first analogue indication signal from the VGA connector ( 33 ) and the second analogue indication signal from the analogue output terminal ( 341 ) of the DVI connector ( 34 ) and selects the signal selected from the first and second analogue indication signals to the single-frequency control unit ( 36 ).