KR100473762B1 - Automatic channel detection method - Google Patents

Abstract

According to the present invention, according to whether or not a signal processing synchronization signal is detected in an input channel signal, an unadjusted signal is divided at predetermined positions by dividing by a predetermined amount of two sets respectively set in both directions from a preset center frequency of the receivable channel. The present invention relates to a method for automatically detecting channel presence so that a channel value can be more accurately determined by detecting and confirming the value of AFT), and synchronizing with an AFT signal by synchronizing with a frequency of a predetermined width shifted from a center frequency of an arbitrary channel. Detecting a signal; A second step of re-detecting an unadjusted signal by tuning to a frequency further tuned in a predetermined width in accordance with the detected two signal values; A third step of determining whether to continue signal detection in a direction opposite to that of the first step according to the value of the signal detected in the second step; A fourth step of redetecting an unadjusted signal by tuning to a frequency having a predetermined width shifted in the opposite direction when determining to continue performing; And a fifth step of determining the presence or absence of a channel based on the signal value detected in the fourth step, so that the channel is more accurately affected by external signal noise, characteristics of components, and even when the broadcasting band is shifted. It is a very practical and excellent invention that can confirm the existence of the signal, and can confirm the presence or absence of the correct channel signal even in an environment where the detection bandwidth of the channel is reduced.

Description

Automatic channel detection method

The present invention relates to a channel presence automatic detection method for dividing and repeating a channel presence detection section. More particularly, the present invention relates to a method for detecting a predetermined channel based on whether a signal processing synchronization signal is detected in an input channel signal. A method for automatically detecting a channel presence by dividing a predetermined amount of two tunes set in both directions from a center frequency of a channel to detect and confirm a value of an unadjusted signal (AFT) at a disassembled position. will be.

An apparatus for automatically detecting the presence or absence of a channel includes: a tuning unit 10 for tuning the signal band corresponding to the channel data applied among the received high frequency signals; A Y / C signal processor 20 for demodulating the tuned output signal and outputting a video signal; And a microcomputer 30 for determining whether a channel signal exists in the currently applied channel from the fine adjustment signal AFT output from the tuning unit 10 and the synchronization signal output from the Y / C signal processing unit 20. It is configured to include.

In the conventional automatic channel presence detection method configured as described above, first, the microcomputer 30 is shifted by 0.5 MHz (8 step = 8 × 62.5 Hz) at the center frequency of the channel to be checked for the presence or absence of a channel signal. The channel data for tuning is applied to the tuning unit 10, and the tuning unit 10 tunes and outputs an input signal at a frequency 0.5 MHz tuned from the center frequency of the confirmation channel. In the tuned state as described above, the tuning unit 10 outputs an auto fine tuning (AFT) signal to the microcomputer 30, and the Y / C signal processing unit 20 performs the tuning output. A synchronization signal is detected from the signal, and the detected result is also transmitted to the microcomputer 30.

The microcomputer 30 checks the value of both input signals, and if both values are HIGH, the microcomputer 30 confirms that a valid signal exists in a channel currently applied to the tuning unit 10 and stores it. If any one is not high, the current channel is skipped and the above process is repeated for the next channel to check whether the channel signal exists for all channels (see FIG. 2).

However, in the channel presence checking method as described above, only the AFT and the synchronization signal are detected to confirm the channel presence. Therefore, the channel is frequently misrecognized due to the high signal generated by external noise or spurious components. Also, the channel of the TV broadcasting band 2MHz away from the cable broadcasting band is set and memorized after confirming the channel, so that the uncertainty of the channel signal is stored in the cable broadcasting band, and as the channel signal is received twice, the automatic band selection is performed. There was a problem that does not work properly.

Therefore, to solve the above problems, a channel presence confirmation method as shown in Fig. 3 is proposed by bidirectional duplex. In this method, the AFT + voltage is checked by -7 step dumming based on the center frequency in the auto-tuning mode. When the two conditions are satisfied, the AFT- voltage is checked by +6 step duplexing based on the center frequency (see Fig. 4).

However, in the proposed method, if a corresponding value is detected in AFT + at -7 step modulation, but a corresponding voltage value is not detected at AFT- at +6 step modulation, a channel skip phenomenon occurs. In case of automatic tuning of ± 0.3MHz duplex channel, it is actually sensitive by the variation of the filter characteristics inside the conventional tuner, the unbalanced signal (AFT) curve characteristics inside the iF integrated circuit (IC), and the wide channel detection range of the micom algorithm. This is because the channel cannot be detected even if the slope is slightly gentle at the tilt position of the input signal. Therefore, the proposed method still has a problem in that, even though a broadcast is being received, a case where the broadcast channel is not memorized when the channel is detected is automatically exceeded.

Accordingly, the present invention has been made to solve the above problems, and an object thereof is to provide an automatic channel presence detection method capable of confirming accurate channel signal presence without being influenced by external noise.

Another object of the present invention is to provide an automatic channel presence detection method capable of accurately checking the presence or absence of a channel signal without skipping a channel even when the detection bandwidth of the synchronization signal is narrowed according to channel signal doublet.

According to an aspect of the present invention, there is provided a method for automatically detecting a channel presence, the method comprising: a first step of detecting a fine-tuned (AFT) signal and a synchronization signal by tuning to a frequency of a predetermined width shifted from a center frequency of an arbitrary channel; A second step of re-detecting an unadjusted signal by tuning to a frequency further tuned in a predetermined width in accordance with the detected two signal values; A third step of determining whether to continue signal detection in a direction opposite to that of the first step according to the value of the signal detected in the second step; A fourth step of redetecting an unadjusted signal by tuning to a frequency having a predetermined width shifted in the opposite direction when determining to continue performing; And a fifth step of determining the presence or absence of a channel based on the signal value detected in the fourth step.

In the method for automatically detecting channel presence according to the present invention, if the fifth step is one of the signal values detected in the fourth step does not satisfy the condition of channel presence, Is a first sub-step of tuning the frequency tuned in the same direction as in the fourth step to redetect the unadjusted signal by a different amount; And a second sub-step of re-determining the presence or absence of a channel based on the signal value detected in the first sub-step.

In the automatic channel presence detection method according to the present invention, the input signal is sequentially tuned to the tuned frequency divided by a predetermined width in a single direction from the center frequency of the channel currently being checked, and the synchronization signal is detected in that state. Check whether the value of the unadjusted signal and the value of the unadjusted signal are adjusted in the opposite direction to the above direction according to the result of the check. It is determined that the signal is present.

In addition, the predetermined width half-tone confirmation in the opposite direction is also divided into narrow widths, and the input signal is tuned at the first set-point two-dividing point to detect and confirm the unadjusted signal. By re-synchronizing the input signal at the second second point and detecting the value of the fine adjustment signal, the presence or absence of a valid signal of the corresponding channel is reconfirmed according to the detection result.

Hereinafter, preferred embodiments of the automatic channel presence detection method according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 5 is a preferred embodiment of the automatic channel presence detection method according to the present invention, which will be described in detail with reference to the apparatus of FIG.

The microcomputer 30 firstly tunes and broadcasts the received channel (S90) and tunes by the tuning unit 10, and then checks whether the Y / C signal processing unit 20 detects a synchronization signal ( S91), if a synchronization signal is not detected, the corresponding channel is passed (S141). If a synchronization signal is detected, the following process is performed.

The microcomputer 30 tunes the frequency tuned by three steps (= 187.5 kHz) in the increasing direction from the center frequency in the tuning unit 10 (S100), and then detects an unadjusted signal (AFT) (S110). If the signal value is 4V or more, the fine adjustment signal value is detected from the current center frequency in the decreasing direction (S120).

If the unadjusted signal value detected in the checking step (S110) is not more than 4V, it is not determined that there is no channel signal, and again tunes to the frequency shifted by 7 steps (= 437.5 kHz) in the increasing direction from the center frequency currently being checked. (S111), the value of the fine adjustment signal is detected again (S115).

At this time, if the detected unadjusted signal value is 4 V or more, the channel detection is performed in the increasing direction from the center frequency in the decreasing direction from the center frequency as in the case of detecting the unadjusted signal value of 4 V or more at the time of the 3 step duplex. The same process is followed. In other words, after tuning to the frequency stepped in the decreasing direction from the center frequency being checked (S120), it is checked whether the value of the detected unadjusted signal is 0.9V or less (S130), and if it is 0.9V or less, It is determined that there is a channel signal in the channel, and the corresponding channel is stored (S142). Even though the unadjusted signal value detected as a result of the tuning is not 0.9 V or less, the 7-step step is performed in the decreasing direction again from the center frequency without passing through the channel. Resynchronization to the frequency (S131), and check the value of the fine-tuned signal once again (S140). At this time, when the checked value is finally 0.9 V or less, the corresponding channel is stored (S142). Otherwise, the channel signal is determined to be absent and the process proceeds to the next channel confirmation step (S141).

FIG. 6 shows an example of a duplex-received broadcast signal, which is identified as a channel presence by three confirmation steps (S110, S115, S130) in the method of double-checking according to FIG.

When the presence or absence of the channel signal is confirmed by the above method, the frequency range of sustaining the HIGH and LOW levels of the preset fine signal is reduced due to the characteristics of the integrated circuit (IC) used in the apparatus. To reduce the bandwidth of the SAW filter in order to improve the adjacent and adjacent channel disturbance ratios, the detection band of the synchronization signal is reduced, as well as the existence of the channel signal even when the input signal is received twice. It will be possible.

In the automatic channel presence detection method according to the present invention as described above, it is possible to more accurately check the existence of the channel signal without being affected by the signal noise or component characteristics and the duplex of the broadcast band applied from the outside. It is a very practical and excellent invention that can confirm the presence of the correct channel signal even in the environment of reduced bandwidth.

1 is a general configuration diagram of the automatic channel presence detection device is implemented,

2 shows channel signal confirmation conditions in a conventional automatic channel presence detection method.

3 is a flowchart illustrating a conventional automatic channel presence detection method.

4 shows channel signal confirmation conditions according to the automatic channel presence detection method according to the method of FIG.

5 is a flowchart illustrating a preferred embodiment of the automatic channel presence detection method according to the present invention;

FIG. 6 illustrates a condition in which a channel input and inputted is channel checked according to the detection method of FIG.

※ Explanation of code for main part of drawing

10: tuning unit 20: Y / C signal processing unit

30: MICOM

Claims (4)

A first step of tuning to a frequency width-shifted at a center frequency of an arbitrary channel and detecting an AFT signal and a synchronization signal; A second step of re-detecting an unadjusted signal by tuning to a frequency further tuned in a predetermined width in accordance with the detected two signal values; A third step of determining whether to continue signal detection in a direction opposite to that of the first step according to the value of the signal detected in the second step; A fourth step of redetecting an unadjusted signal by tuning to a frequency having a predetermined width shifted in the opposite direction when determining to continue performing; And And a fifth step of determining whether a channel is present based on the signal value detected in the fourth step. The method of claim 1, The predetermined width shift amount of the first step and the second step is a frequency separation amount corresponding to 3 steps and 4 steps, respectively. The method of claim 1, The fifth step, If any one of the signal values detected in the fourth step does not satisfy the condition of channel presence, the frequency is equalized in the same direction as in the fourth step by an amount different from the amount of doubling in the fourth step. A first substep of tuning to redetect the unadjusted signal; And And a second substep of re-determining the presence or absence of a channel based on the signal value detected in the first substep. The method of claim 3, The predetermined width shift amount in the fourth step is a frequency separation amount corresponding to three steps, The same amount of coarse duplexing of different magnitudes in the first sub-step is a frequency separation amount corresponding to 7 steps.