KR0144214B1 - Method for selecting a desire channel - Google Patents

Abstract

The present invention provides a channel tuning method of a receiving device, comprising: determining (21) whether to apply a channel probe mode; Detecting (22, 23, 24, 25, 26, 27, 28) the center frequencies of all receivable channels in the channel search mode; Determining (31) whether a signal for selecting a predetermined channel according to a user's selection is input; Receiving (32, 33) a signal of a frequency band corresponding to the stored center frequency when a signal for selecting a predetermined channel is input; And re-detecting the center frequency by varying the reception frequency band to continue receiving the frequency band of the detected band, and re-saving the detected center frequency (34, 35, 36).

That is, according to the present invention, the channel to be broadcasted in the channel search mode and the PLL data for receiving the center frequency of the channel are stored. When a predetermined channel is selected, the PLL data stored in the channel search mode is selected. By receiving the signal of the channel and re-detecting the center frequency band, there is an effect that the time required for detecting the center frequency of the selected channel can be shortened.

Description

Channel Tuning Method

1 is a block diagram of an imaging apparatus for performing a channel tuning method according to the present invention;

2 is a flowchart of an image processing apparatus for performing a channel tuning method according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Microcomputer 2: Key metrics

3: Tuner 4: Sync detector

5: signal processing unit

The present invention relates to a receiving apparatus, and more particularly, to a channel tuning method that enables to easily tune the center frequency (Center Frequence) of the channel frequency band to be tuned.

In radio broadcasting and television broadcasting, broadcasting of various frequency bands, that is, multiple channels, is performed. In order to receive signals in these frequency bands, a tuner must be tuned to the center frequency of the frequency band to be received.

The NTSC (Frequence Syncronizing) method of the National Television System Committe (FSC) employs a method using an AFT voltage to tune the tuner of the receiver to the center frequency of each channel. That is, when the PLL data for tuning the frequency of each channel is stored in the micom of the receiving apparatus and the user selects a predetermined channel by dial or the like, the micom applies the PLL data of the selected channel to the tuner. A phase lock loop is formed in the tuner to control the oscillation frequency of the voltage controlled oscillator according to the PLL data to receive the frequency signal of the channel selected by the user.

However, since the center frequency of a frequency band signal transmitted from a broadcasting station varies slightly depending on the region or environment, it is necessary to change the oscillation frequency of the voltage controlled oscillator in order to synchronize the center frequency with the tuner. To this end, in the FS scheme, the tuner outputs the AFT voltage according to the received signal level, and the microcomputer changes the PLL data according to the AFT voltage. In other words, in the FS method, the PLL data output from the microcomputer is changed to slightly change the tuner's reception frequency, and the microcomputer detects the center frequency of the reception frequency band having the best reception state by the output AFT voltage. The PLL data at that time was continuously applied to the tuner.

However, this conventional method is configured to continue to execute every time a user tunes into a given channel, and since the microcomputer needs a considerable time to detect the center frequency of the selected channel, the signal where the destination is poorly received during that time is used. There was a inconvenience to continue to receive. In particular, in cable televisions such as the United States, since the center frequency can be varied from about + 2MHZ to -1.25MHZ, it takes considerable time to detect the center frequency by the conventional method.

The present invention has been made to solve such a problem, and an object of the present invention is to detect and store the center frequencies of all receivable channels, and to redetect the center frequencies from the stored center frequencies when the channels are re-tuned. It is an object of the present invention to provide a channel tuning method for shortening the detection time of a center frequency.

According to another aspect of the present invention, there is provided a channel tuning method of a receiving device, comprising: determining whether a channel is in a search mode; Detecting and storing center frequencies of all receivable channels in the channel search mode; Determining whether a signal for selecting a predetermined channel according to a user's selection is input; Receiving a signal of a frequency band corresponding to the stored center frequency when the signal for selecting a predetermined channel is input; A channel tuning method comprising varying a reception frequency band, redetecting a center frequency to continuously receive a frequency band of the detected band, and re-storing the detected center frequency.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic block diagram of a receiving apparatus for implementing the present invention. In this embodiment, an example of a video apparatus for receiving an image signal is given.

As shown in the drawing, a key matrix 2 is connected to the microcomputer 1, and the key matrix 2 has a channel selection key for selecting a reception channel in addition to various function keys for controlling the driving of the imaging apparatus according to the present invention. And channel search keys for setting the channel search mode and output a key signal corresponding to the selected, i.e., pressed key.

The microcomputer 1 increases this configuration by scanning keys of the same key matrix, that is, controls the driving of the image processing apparatus in response to the input key signal, and as can be seen from the description below, the channel selection key is pressed. The PLL data of the channel corresponding to the pressed key is applied to the tuner 3, and the center frequency of the frequency band being received by the tuner 3 is detected by the AFT voltage applied from the tuner 3.

In addition, the synchronization detector 4 is connected to the microcomputer 1, and the microcomputer 1 determines whether to receive a predetermined video signal according to the synchronization signal applied from the synchronization detector 4.

As described above, the tuner 3 which inputs the PLL data from the microcomputer 1 has a phase lock loop formed therein as in the prior art, so that the antenna is measured by measuring the oscillation frequency of the voltage controlled oscillator according to the PLL data. Through (ANT), the user receives the frequency signal of the channel selected by the user. The tuner 3 is also configured to apply the AFT voltage to the microcomputer 1 according to the level of the signal received via the antenna ANT.

In this way, the signal of the frequency band received by the tuner 3 is processed by the signal processor 5 and applied to the monitor and the speaker. In addition, the signal received by the tuner 3 is applied to the synchronization detector 4, and the synchronization detector 4 detects whether these signals contain a synchronization signal, that is, a horizontal synchronization signal or a vertical synchronization signal. Applied to 1). The reason for detecting the synchronization signal using the synchronization detection unit 4 as described above can be understood from the following description that the horizontal and vertical synchronization signals are included in the video signal transmitted from the broadcasting station. This is because it is possible to determine whether or not the frequency band received in 3) is a frequency band for transmitting a video signal from a broadcasting station.

2 (a) and 2 (b) show a flowchart of a program for the microcomputer 1 to perform the channel tuning method of the present invention in the image processing apparatus having the above-described configuration.

In FIG. 2, (a) is a flowchart for performing a channel search mode for searching and storing channels of all frequency bands in which broadcasting is performed, as described below.

That is, the microcomputer 1 determines whether the channel search mode is set by pressing the channel search key of the key matrix 2 in step 21 and proceeds to step 22 when the channel search mode is set. In step 22, the microcomputer 1 sets the lowest channel among the channels of the broadcasting frequency band where the batting is performed, and applies the PLL data corresponding to the lowest channel set in step 23 to the tuner 3.

Therefore, the tuner 3 will receive the frequency band signal of the lowest channel according to the PLL data of the microcomputer 1. At this time, the channel frequency band received by the tuner 3 may be a frequency band in which video broadcasting is being transmitted from a broadcasting station, or may be a frequency band not being transmitted. In order to determine this, the microcomputer 1 proceeds to step 24 and determines whether the synchronization signal is included in the signal received by the tuner 3. That is, the microcomputer 1 determines whether the synchronization signal detected from the synchronization detection unit 4 is applied in step 24 and proceeds to step 25 if a synchronization signal is applied, and if the synchronization signal is not applied, step 28. To proceed.

The microcomputer 1 proceeds to step 25 and changes the PLL data currently applied to the tuner 3 to a minute, and proceeds to step 25 to correspond to the frequency band received by the tuner 3 according to the changed PLL data. Determine whether the center frequency of the channel frequency band. That is, since the tuner 3 outputs the AFT voltage synchronized with the frequency band being received, the microcomputer 1 repeats steps 25 and 26 several times, when the tuner 3 is applied to the corresponding channel when the highest AFT voltage is applied. Is to be synchronized to the center frequency. At this time, since the microcomputer 1 is programmed to apply the PLL data to the tuner 3 in the direction in which the AFT voltage increases, these steps 25 and 26 may be easily implemented.

If the center frequency band is detected in step 26, the microcomputer 1 proceeds to step 27 and in step 25, 26 the PLL data which causes the tuner 3 to receive the center frequency band of the current channel. Save and proceed to step 28.

In step 27, the microcomputer 1 determines whether the channel of the frequency band being currently received by the tuner 3 is the highest channel, and terminates all processes in the case of the highest channel, but the tuner 3 if the channel is not the highest channel. Increases the channel of the frequency band being received by one channel, that is, sets the next channel to the channel of the frequency band to be received by the tuner 1 and returns to step 23.

That is, when the channel search mode is set, the microcomputer 1 sequentially stores step-by-channel PLL data for each channel so that the center frequencies of the channels can be received by sequentially performing steps 21-29 for all channels.

FIG. 2B shows a flow chart of the internal program of the microcomputer 1 for receiving a broadcast signal of a channel desired by a user using PLL data stored to receive a center frequency for each channel according to a channel search mode. have.

As shown, the microcomputer 1 determines in step 31 whether the channel selection key of the key matrix 2 has been pressed, that is, the user has selected a predetermined channel.

As a result of the determination in step 31, if a predetermined channel is selected, the microcomputer 1 proceeds to step 32 in which the synchronization signal is applied from the synchronization detector 4, i.e., the image of the predetermined frequency band from the broadcasting station to the selected channel. Determine if a signal is being sent. As a result of the determination in step 33, if a synchronization signal is applied from the synchronization detector 4, the microcomputer 1 proceeds to step 34, and micro-changes the PLL data output in step 32 to the tuner 3 to apply it. do. Then, the microcomputer 1 proceeds to step 35 and determines whether the frequency band received by the tuner 3 is the center frequency of the channel frequency band according to the changed PLL data.

At steps 34 and 35, the intermediate frequency band is detected again from the PLL data detected and stored as the PLL data for receiving the center frequency band of the corresponding channel in steps 26 and 29 of FIG. Therefore, the detection time will be relatively reduced. That is, the AFT voltage of the tuner 3 is stepped up and down in proportion to the tuned state with the reception frequency, and the center frequency band is minutely changed according to the region and environment, and the changed state is rarely changed again. In FIG. 2A, the time required for redetecting the center frequency band from the PLL data stored as the center frequency band is extremely short.

Then, the microcomputer 1 proceeds to step 36 and continuously applies the PLL data of the intermediate frequency band detected in steps 34 and 35 to the tuner 3, thereby causing the tuner 3 to center the channel. The tuned PLL data is re-stored as PLL data capable of receiving the center frequency band of the channel while still being tuned to the frequency, and used as the PLL data required in step 32 when this channel is selected again.

As described above, the present invention stores the PLL data for receiving the channel and the center frequency of the channel in which the broadcast is performed in the channel search mode, and selects the PLL data stored in the channel search mode when the predetermined channel is selected. By re-detecting the center frequency band while receiving the signal of the channel, it is possible to shorten the time required to detect the center frequency of the selected channel.

Therefore, the present invention has an effect of significantly reducing the time required for detecting the center frequency of the selected channel, so that the signal of the desired channel can be accurately received within a short time after the channel is selected.

Claims (1)

CLAIMS 1. A channel tuning method of a receiver, comprising: determining (21) whether a channel search mode; Detecting (22, 23, 24, 25, 26, 27, 28) the center frequencies of all receivable channels in the channel search mode; Determining (31) whether a signal for selecting a predetermined channel according to a user's selection is input; Receiving (32, 33) a signal of a frequency band corresponding to the stored center frequency when a signal for selecting a predetermined channel is input; And re-detecting the center frequency by varying the reception frequency band to continuously receive the frequency band of the detected band, and resave (34, 35, 36) the detected center frequency.