KR19980023519A - How to fine tune your channel - Google Patents

Abstract

The present invention relates to a receiving apparatus which adjusts the tuner 30 receiving frequency with PLL data and finely adjusts the receiving frequency according to the AFT voltage of the tuner 30. The method 21 determines whether the channel tuning mode is set. Wow; If a channel tuning mode is set, searching (22) for changing the PLL data to find a channel where a synchronization signal is detected; If the synchronization signal is detected, changing the PLL data to a predetermined range, and storing (23, 24, 25) the PLL data from which the synchronization signal is detected; Calculating an average value A of the stored PLL data (26); Set the window for the variation range of the PLL data centered on the average PLL data A, and set the PLL data for which the AFT voltage of the tuner 30 is optimal within the set window range as the PLL data of the corresponding channel. Steps 27, 28 and 29 are provided.

In other words, the present invention has an effect that more efficient tuning can be performed by detecting all PLL data that can detect a synchronization signal per channel and setting the window range to the average value of the PLL data.

Description

How to fine tune your channel

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a channel fine tuning method, and more particularly, to a channel fine tuning method that enables faster channel tuning in video equipment such as a video cassette recorder or a television.

In general, the channel auto-tuning function determines whether a broadcast signal is input among all broadcast channels as the presence or absence of a synchronization signal and stores the channel to which the broadcast signal is input in a memory, so that when a user switches a channel, that is, a channel up / down It is a function to facilitate channel switching by only up / down channels where broadcast is performed at a time.

On the other hand, in order to receive signals in these frequency bands in a television or cable broadcasting system in which various frequency bands, that is, broadcasts of a plurality of channels, are tuned to the carrier frequency of the channel to be received.

NTSC (National Television System Committe) FS (Frequency Synchronizing) method adopts AFT (Automatic Fine Tunning) voltage to tune the tuner of the receiver to the carrier frequency of each channel. . That is, when the PLL data for tuning the frequency of each channel is stored in the memory of the microcomputer of the receiver and the user selects a predetermined channel by dial or the like, the microcomputer applies the PLL data of the selected channel to the tuner.

On the other hand, 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 carrier frequency of the signal transmitted from the 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 carrier frequency with the tuner.

To this end, in the FS scheme, the AFT voltage is output according to the frequency of the IF signal output from the tuner, and the microcomputer is configured to finely change the PLL data according to the AFT voltage.

That is, in the FS method, the PLL data output by the microcomputer is changed to check whether the synchronization signal is detected while changing the local oscillation frequency of the tuner slightly, and when the synchronization signal is detected, the broadcast signal is recognized and the channel fine adjustment, , The window search will be performed.

That is, an intermediate frequency (IF) signal outputted from the tuner by finely changing the PLL data in predetermined step units so that the applied AFT voltage becomes an intermediate voltage within a predetermined window range (for example, 2.8-3.8 V). The frequency of is set to 45.75 MHz (for NTSC).

More specifically, FIG. 1 is a waveform diagram of an AFT voltage. First, the AFT HIGH voltage (about 2.8V) is found, and then the AFT LOW voltage (about 1.8V) is found, and then the AFT HIGH voltage is applied to the tuner when the AFT HIGH voltage is found. When the PLL data and the AFT LOW voltage are found, the channel fine tuning is terminated by applying to the tuner the intermediate value of the PLL data applied to the tuner, that is, the PLL data value applied with the optimum AFT voltage.

However, such a channel automatic tuning function in the related art sets the tuning value when the optimum AFT voltage is detected within the window range centered on the synchronization signal after the detection of the synchronization signal to the optimum channel so that the synchronization signal is within the window range. In the case of detection of R, the optimum AFT voltage could not be detected, resulting in incomplete tuning.

That is, as described above, the carrier frequency of the signal transmitted from the broadcasting station may change slightly depending on the region or environment, and the frequency band in which the synchronization signal per channel is detected may be distributed in various bands. However, since there is only one frequency band of a synchronization signal having an optimal broadcast signal among these synchronization signals, there is a problem that accurate tuning is not performed when the optimum AFT voltage within the window range is detected just because the synchronization signal is detected. there was.

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and an object of the present invention is to provide a method for fine tuning a channel, which enables optimal tuning even when a synchronization signal exists in a plurality of frequency bands.

According to an aspect of the present invention, there is provided a method for fine tuning a channel, the method comprising: adjusting a tuner reception frequency to PLL data and finely adjusting a reception frequency according to an AFT voltage of a tuner, the method comprising: determining whether a channel tuning mode is set; If the channel tuning mode is set, searching for a channel where a synchronization signal is detected by changing PLL data; If the synchronization signal is detected, changing the PLL data to a predetermined range, and storing the PLL data from which the synchronization signal is detected; Calculating an average value A of the stored PLL data (26); And setting a window for the variation range of the PLL data centering on the average PLL data A, and setting the PLL data for which the AFT voltage of the tuner is optimal within the set window range as the PLL data of the corresponding channel.

1 is an AFT voltage waveform diagram for explaining the present invention

2 is a hardware block diagram for general channel fine tuning

3 is a flowchart illustrating a channel fine tuning process according to the present invention.

Explanation of symbols on the main parts of the drawings

10: key input unit 20: microcomputer

30 tuner unit 40 synchronization detection unit

50: signal processing unit

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

FIG. 2 is a hardware block diagram for channel fine tuning according to the present invention, and includes a key input unit 10, a microcomputer 20, a tuner 30, a synchronization detector 40, and a signal processor 50 as shown. do.

In this configuration, the key input unit 10 includes a plurality of keys including a tuning key for channel automatic tuning, and applies a key signal corresponding to the user's key operation to the microcomputer 20, and is normally input from a remote location. This remote control is used and the key signal carried on the infrared carrier from the remote control is detected and applied to the microcomputer 20.

The microcomputer 20 is a means for controlling the overall operation of the video device on the basis of the key signal from the key input unit 10, and the tuning key input through the key input unit 10 as can be seen from the description below. The PLL data for tuning is output to the tuner 30 based on the signal, and channel selection is controlled based on the presence or absence of a synchronization signal from the synchronization detector 40 and the AFT voltage from the tuner 30.

Also, the tuner 30 is configured to receive a broadcast signal of a channel corresponding to PLL data, which is a tuning signal of the microcomputer 20, among a plurality of broadcast frequency signals transmitted from the broadcasting system, and the tuner 30 is in a tuned state. AFT voltage according to the applied to the microcomputer 20.

In addition, the tuner 30 is connected to the sync detector 40, and the sync detector 40 separates the sync signal from the broadcast signal received from the tuner 30 and applies it to the microcomputer 20.

On the other hand, the signal processing unit 50 analyzes the video signal and the audio signal from the broadcast signal from the tuner 30 under the control of the microcomputer 20 and processes them into signals that are easy to display and output, respectively, to monitors and speakers. The output allows the user to watch the broadcast.

Next, the channel fine tuning process according to the preferred embodiment of the present invention will be described in detail with reference to the flowchart of FIG. 3.

First, when the tuning key signal is applied from the key input unit 10 in step 21, the microcomputer 20 sequentially reads the PLL data corresponding to the lowest channel to the highest channel from the memory (not shown) to the tuner 30. The tue 30 outputs a broadcast signal received and tuned to a channel corresponding to the applied PLL data, and outputs an AFT voltage corresponding to a reception state of the broadcast signal.

At this time, the synchronization detector 40 receives the broadcast signal tuned to the corresponding channel from the tuner 30 and detects the synchronization signal to be applied to the microcomputer 20.

Then, the microcomputer 20 determines whether the synchronization signal is applied from the synchronization detector 40 in step 22, and proceeds to step 23 when the synchronization signal is applied. In step 23, the microcomputer stores the PLL data from which the synchronization signal is detected, and proceeds to step 24 to determine whether or not the final PLL data per channel. That is, when the synchronization signal is detected, the microcomputer 20 of the present invention changes the PLL data (final PLL data per channel) from the PLL data where the synchronization signal is detected to a predetermined range (step 25), and continuously determines whether the synchronization signal is detected. Thus, the PLL data for which the synchronization signal is detected is continuously stored. As described above, the reason why the PLL data is changed and the synchronization signal is detected even when the synchronization signal is detected may be that a plurality of frequency bands in which the synchronization signal is detected per channel may exist, thus detecting all frequency bands in which the synchronization signal is detected per channel. To do that.

Therefore, in step 24, the final PLL data per channel is set to a range of PLL data that is considered to correspond to this channel after one sync signal is detected (if it is detected, it is determined to be one channel). It should be understood that such a technique can be easily set by those skilled in the art.

The microcomputer 20 proceeds to step 26 and obtains the average value A of the PLL data detected in step 23, that is, the PLL data from which the synchronization signal is detected, and the window range centering on the PLL data A. Set (step 27). Then, the microcomputer 20 changes the PLL data within the set window range and searches for the optimal AFT voltage (step 28), and sets the PLL data when the optimum AFT voltage is detected as the PLL data of the corresponding channel. (Step 29).

That is, according to the present invention, when one sync signal is detected as in the related art, instead of setting a window centering on the PLL data of the sync signal, all of the detected signals are detected within a predetermined range around the frequency band where the sync signal is detected. The synchronization signal is detected, and a window is set centering on the average value of the PLL data from which the synchronization signal is detected.

As described above, according to the present invention, there is an effect that more efficient tuning can be performed by detecting all PLL data that can detect a synchronization signal per channel and setting the window range to the average value of the PLL data.

Claims (1)

In the receiving device for adjusting the reception frequency of the tuner 30 to PLL data and finely adjusting the reception frequency according to the AFT voltage of the tuner 30, Determining (21) whether the channel tuning mode is set; If the channel tuning mode is set, searching for a channel in which a synchronization signal is detected by changing the PLL data; If the synchronization signal is detected, changing the PLL data to a predetermined range, and storing (23, 24, 25) the PLL data from which the synchronization signal is detected; Calculating (26) an average value (A) of the stored PLL data; Set the window for the variation range of the PLL data centering on the average PLL data A, and set the PLL data for which the AFT voltage of the tuner 30 is optimal within the set window range as the PLL data of the corresponding channel. And channel (27, 28, 29).