KR20010010167A - Method for setting channel automatically - Google Patents

Abstract

The present invention relates to a channel setting method of a tuner, and more particularly, to an automatic channel setting method for shortening an automatic channel setting time for automatically setting a channel in which a broadcast signal exists by searching all channels received by the tuner.

The present invention comprises the steps of (a) tuning a channel sequentially from the lowest channel to the highest channel, and (b) generating control data corresponding to the local oscillation center frequency F0 for the channel tuned in step (a). (C) fine tuning by oscillation frequency of the local oscillator generated corresponding to the control data of step (b), and then determining whether the tuning point is at a positive tuning point, (d) said step (c) Storing the corresponding channel number in the memory and feeding back to the step (a); and (e) if the determination result of the step (c) is not the tuning point, the control. And increasing the data at a minimum step frequency from the fine tuning minimum frequency and feeding back to the step (c). Accordingly, there is an effect that the automatic channel setting time can be shortened.

Description

Method for setting channel automatically {Method for setting channel automatically}

The present invention relates to a channel setting method of a tuner, and more particularly, to an automatic channel setting method for shortening an automatic channel setting time for automatically setting a channel in which a broadcast signal exists by searching all channels received by the tuner.

In general, a method of selecting a broadcast channel by the tuner is to manually tune each channel, check whether a broadcast signal exists in the tuned channel, and then set the channel and automatically search all channels to determine whether or not to tune correctly. There is a method of determining and storing a channel number in which a broadcast signal exists in a memory and setting the same. This is called an automatic channel setting method.

However, the conventional channel setting method according to the prior art PLL for controlling the local oscillation frequency of the automatic fine tuning (AFT) circuit to determine whether the broadcast signal is detected in the tuned channel while increasing the channel sequentially (Phase Locked Loop) Increases the data from F0-500Khz (where F0 is the local oscillation center frequency) to F0 + 500Khz in order by a certain step unit (eg 251Khz), and determines whether there is a broadcast signal or not. It was. However, in general, despite the positive tuning point is taken in F0, there is a problem that takes a lot of time when automatic channel setting due to determining the presence or absence of a broadcast signal from F0-500Khz.

The technical problem to be achieved by the present invention is to first determine whether there is a positive tuning point at the center local oscillation center frequency (F0) at the time of automatic channel setting in order to solve the above-described problem, and if the positive tuning point exists, the number of the corresponding channel To provide an automatic channel setting method for storing the data in the memory.

1 is a block diagram of a tuner to which the present invention is applied.

2 is a flowchart of an automatic channel setting method according to the present invention.

3 is a graph illustrating a relationship between positive tuning points according to AFT voltages.

In order to achieve the above technical problem, the automatic channel setting method according to the present invention comprises the steps of: (a) tuning to a channel sequentially increasing from the lowest channel to the highest channel, (b) step (a) Generating control data corresponding to the local oscillation center frequency (F0) for the channel tuned by (c) after fine tuning by the oscillation frequency of the local oscillator generated corresponding to the control data of the step (b); Determining whether the tuning point is at the positive tuning point, (d) if the tuning point is at the positive tuning point, storing the corresponding channel number in a memory and feeding back to the step (a); and e) If the determination result of step (c) is not at the positive tuning point, the control data is increased by a predetermined step interval from the minimum fine tuning frequency. To feed back to step (c).

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

1 is a tuner circuit to which the present invention is applied and includes an antenna 101, a tuning unit 102, an amplifying unit 103, a mixing unit 104, a local oscillating unit 105, an AFT unit 106, and a control unit 107. Memory 108 is provided.

The operation of these configurations is as follows.

The antenna 101 receives broadcast signals of all broadcast channels transmitted from broadcast stations.

The tuning unit 102 tunes and outputs only the broadcast signal of the tuned channel according to the channel selection signal applied from the control unit 107.

The amplifier 103 amplifies the video signal and the audio signal included in the tuned channel.

The mixing unit 104 converts the local oscillation frequency applied by the local oscillator 105 and the broadcast signal applied by the amplifying unit 103 to convert the video signal and the audio signal of the intermediate frequency.

AFT (Automatic Fine Tuning) is PLL (Phase Locked) so that the oscillation frequency of the local oscillator 105 can be changed by the change of ambient temperature or time, so that the image intermediate frequency of 45.75MHz (41.25MHz for voice) is exactly. Loop) adjusts the local oscillation frequency by the AFT voltage output from the circuit.

When the automatic channel setting command is input by the key input of the key input unit 109, the control unit 107 outputs a channel selection signal to the tuning unit 1020 to sequentially select a channel from the lowest channel to the highest channel. PLL data for determining the oscillation frequency of 105 is output to the local oscillator 105. Then, it is determined whether the AFT voltage exists at the positive tuning point.

Next, the present invention will be described in detail with reference to the flowchart of FIG. 2 with reference to the block diagram of FIG. 1.

In step 201, it is determined whether an automatic channel setting command has been input. That is, the controller 107 determines whether the user inputs the automatic channel setting command through the key input unit 109.

In step 202, when the automatic channel setting command is input as a result of the determination in step 201, the tuning unit 102 applies a channel selection signal for tuning the lowest channel CH _min .

In step 203, the value of D (F), which is PLL data for determining the oscillation frequency of the local oscillator 105, is determined as data corresponding to the local oscillation center frequency F0 of the local oscillator 105, and the local oscillator 105 is determined. To apply.

In step 204, the current tuning point by the local oscillation frequency value generated in the local oscillator 105 by D (F0) applied in step 203 using the AFT voltage applied in the AFT section 106 is a positive tuning point. The control unit 107 determines whether there is. Here, the AFT voltage is a rectified voltage obtained by FM detection of the carrier of the video signal converted to the intermediate frequency output from the mixing unit 104.

3 is a diagram illustrating a relationship between positive tuning points according to AFT voltages. Here, if the AFT voltage is included in the range between Vdown and Vup, it means that the AFT is tuned.

Therefore, the controller 107 determines whether the AFT voltage V _AFT is included in the range between Vdown and Vup to determine whether or not positive tuning is performed.

In step 205, if it is determined that the AFT voltage V _AFT is within the range between Vdown and Vup as a result of the determination in step 204, it means that a broadcast signal exists in the currently tuned channel. The number of channels is stored in memory 108.

In step 206, it is determined whether the currently tuned channel corresponds to the highest channel, and when all channels have been searched when the channel corresponds to the highest channel, the process ends.

In step 207, if the channel currently tuned as the result of the determination in step 206 is not the highest channel, the channel selection signal of the channel selection signal is increased by " 1 " and then fed back to step 203.

In step 208, when the determination result of step 204 is that the AFT voltage V _AFT is not included in the range between Vdown and Vup, i.e., not tuned correctly, the PLL data determines the oscillation frequency of the local oscillator 105. The value of D (F) is changed to data corresponding to the minimum frequency F0-α of the fine tuning range and applied to the local oscillator 105.

In step 209, the controller 107 determines whether the AFT voltage V _AFT applied by the AFT unit 106 is included in the range between Vdown and Vup after applying the changed value of D (F), and Vdown and Vup Step 205 is executed in the case where it is in the range between and at a positive tuning point.

In step 210, if the AFT voltage V _AFT is not included in the range between Vdown and Vup as a result of the determination in step 209, that is, when not tuned correctly, the PLL data determines the oscillation frequency of the local oscillator 105. It is determined whether the value of D (F) is smaller than the data corresponding to the maximum frequency F0 + α of the fine tuning range.

In step 211, when the value of D (F), which is the PLL data, is smaller than the data corresponding to the maximum frequency (F0 + α) of the fine tuning range, the step 1 determines the value of the frequency F of fine tuning by one step. (ΔF) The feedback is made back to step 209 after changing to increased PLL data.

In step 212, if the value of D (F), which is the PLL data, is greater than or equal to the data corresponding to the maximum frequency (F0 + α) of the fine tuning range, in step 212, no positive tuning point exists in the corresponding channel. If not, it means that a broadcast signal does not exist and thus the corresponding channel number stored in the memory 212 is deleted.

According to this operation, since there is a high probability that the broadcast signal exists in the tuned channel in most cases at the center frequency of the local oscillator, fine tuning is performed without performing the above steps 208 to 212 in most cases. You can save the channel and save the channel by automatically saving the channel.

As described above, according to the present invention, the automatic channel setting time can be shortened by judging whether there is a positive tuning point at the local oscillation center frequency F0 at the time of automatic channel setting.

Claims (3)

In the automatic channel setting method, (a) tuning while sequentially increasing channels from the lowest channel to the highest channel; (b) generating control data corresponding to the local oscillation center frequency F0 for the channel tuned in step (a); (c) determining whether the tuning point is at the positive tuning point after fine tuning by the oscillation frequency of the local oscillator generated corresponding to the control data of step (b); (d) if the determination result of step (c) is at the right tuning point, storing the corresponding channel number in a memory and feeding back to step (a); And (e) if the determination result of step (c) is not at the right tuning point, increasing the control data from the fine tuning minimum frequency at a predetermined step interval and feeding back to the step (c). Automatic channel setting method. The automatic channel setting method as claimed in claim 1, wherein in step (c), whether the tuning point is a positive tuning point is determined using an AFT (Automatic Fine Tuning) voltage. 3. The automatic channel setting method as claimed in claim 2, wherein the AFT (Automatic Fine Tuning) voltage is a voltage associated with a change in the local oscillation frequency of the tuner.