KR19990042776A - Auto Tuning Method of Broadcast Receiver - Google Patents

Abstract

The present invention relates to an automatic tuning method of a broadcast receiver for tuning a center frequency of a channel to be tuned to a tuner using the AFT voltage after detecting an AFT voltage while varying a frequency applied to a tuner. A first step of detecting the AFT voltage by tuning the tuner at a predetermined center frequency corresponding to the channel; Until the AFT voltage is located in a narrow region having a negative slope, the AFT voltage is alternately changed in units of a variable frequency based on the center frequency tuned to the tuner in the first step, and the AFT voltage is varied. Detecting a second step; When the AFT voltage located in the narrow region is detected in the second step, the AFT voltage is varied in a predetermined step frequency unit at a predetermined center frequency that is variable in the second step until an AFT voltage within a predetermined predetermined voltage range is detected. Detecting a third step; And a fifth step of tuning the tuner to a frequency applied to the tuner when the AFT voltage is detected when the AFT voltage is detected in the third step. By providing an automatic tuning method, the time required for automatic tuning can be shortened.

Description

Auto Tuning Method of Broadcast Receiver

The present invention relates to a broadcast signal reception method of a broadcast receiver, and more particularly, to a broadcast receiver capable of reducing the time required to tune a tuner to a center frequency of a channel to be tuned. The automatic tuning method.

In general, broadcasting receivers including radio broadcasting and television broadcasting are broadcast in various frequency bands, that is, multiple channels. In order to receive signals in these frequency bands, a tuner is provided at a center frequency of a frequency band to be received. It should be synchronized.

In the NTSC (Frequence Syncronizing) method, the AFS (Auto Fine Tunning) voltage is used to synchronize the tuner of the receiver to the center frequency of each channel. It will be described schematically with reference to Figure 1 as follows.

FIG. 1 is a block diagram illustrating a general automatic tuning device, and includes a key input unit 100, a microcomputer 200, a storage unit 300, a tuner unit 400, and an AFT voltage detector 500.

Referring to the figure, after storing the PLL data for tuning the center frequency of each channel in the storage unit 300 provided in the apparatus for receiving a broadcast signal, if the user selects a predetermined channel, the microcomputer 200 Referring to the data stored in the storage unit 300, the PLL data corresponding to the channel selected by the user is applied to the tuner unit 400.

On the other hand, a phase lock loop is formed in the tuner 400, and the frequency signal of the channel selected by the user is received by controlling the oscillation frequency based on the PLL data applied from the microcomputer 200. Will be done.

In practice, however, the frequency of broadcasting varies from channel to channel, depending on the characteristics of the transmission equipment of the local broadcasting station, or the frequency control oscillator. It is necessary to change the oscillation frequency of.

To this end, in the related art, the tuner unit 400 is controlled by the ATF voltage detector 500 while changing the PLL data output from the microcomputer 200 and changing the reception frequency in units of step frequency (Step Frequency = 62.5KHz or 31.25KHz). An AFT voltage corresponding to the signal level received at was detected and provided to the microcomputer 200.

The microcomputer 200 refers to the AFT voltage provided by the AFT voltage detector 500, and detects the frequency having the best reception state, that is, the center frequency of the reception frequency band, and then tunes the tuner 400 to be fixed to the detected center frequency. ) Was controlled.

However, in such a conventional method, there is a problem that it takes too much time to adjust to the actual center frequency because the unit of the step frequency is too small when the error between the actual center frequency and the PLL data is severe.

The present invention has been made in view of the above-described problems, and an object of the present invention is to search for an AFT voltage while varying PLL data in large frequency units until a predetermined range of AFT voltage is detected, and then the AFT voltage is within a predetermined range. When detected in the present invention, there is provided an automatic tuning method of a broadcast receiver configured to tune the tuner to the center frequency while varying the PLL data in small frequency units.

In order to achieve the above object, the present invention, after detecting the AFT voltage while varying the frequency applied to the tuner, and using the AFT voltage to automatically tune the center frequency of the channel to tune to the tuner A tuning method, comprising: a first step of detecting an AFT voltage by tuning the tuner at a predetermined center frequency corresponding to a channel to be tuned; Until the AFT voltage is located in a narrow region having a negative slope, the AFT voltage is alternately changed in units of a variable frequency based on the center frequency tuned to the tuner in the first step, and the AFT voltage is varied. Detecting a second step; When the AFT voltage located in the narrow region is detected in the second step, the AFT voltage is varied in a predetermined step frequency unit at a predetermined center frequency that is variable in the second step until an AFT voltage within a predetermined predetermined voltage range is detected. Detecting a third step; And a fifth step of tuning the tuner to a frequency applied to the tuner when the AFT voltage is detected when the AFT voltage is detected in the third step. Provides an automatic tuning method.

1 is a block diagram showing a general automatic tuning device;

2 is a detailed flowchart illustrating an automatic tuning method of a broadcast receiver according to the present invention;

3 is a waveform diagram showing a general AFT waveform;

<Description of Symbols for Main Parts of Drawings>

100: key input unit 200: microcomputer

300: storage unit 400: tuner unit

500: AFT voltage detector

The above and other objects and advantages of the present invention will become more apparent from the preferred embodiments described below with reference to the accompanying drawings.

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

1 is a block diagram illustrating a general automatic tuning device, and includes a key input unit 100, a microcomputer 200, a storage unit 300, a tuner unit 400, and an AFT voltage detector 500. In order to perform the automatic tuning method of the broadcast receiver according to the present invention, each of the following functions is performed.

First, the key input unit 100 is formed to include a plurality of channel selection keys such as a number key or a direction key, and generates and provides a key signal corresponding to a user's key operation to the microcomputer 200.

The microcomputer 200 controls the overall operation of the broadcast receiver in response to the signals provided from each of the key input unit 100 and the constituent members of the broadcast receiver. In particular, when the channel selection key signal is applied from the key input unit 100, the microcomputer In operation 200, the PLL data corresponding to the key signal is extracted from the storage 300 and provided to the tuner 400. In addition, the microcomputer 200 adjusts the PLL data provided to the tuner 400 with reference to the AFT voltage provided by the AFT voltage detector 500 to tune the tuner 400 to the carrier frequency.

In the storage unit 300, PLL data capable of tuning the center frequency of each channel is preset and stored.

The tuner unit 400 includes a phase lock loop (not shown), and by controlling the oscillation frequency of the voltage controlled oscillator (not shown) according to the PLL data applied by the microcomputer 200, Receive the frequency signal of the channel selected by the user.

The AFT voltage detector 500 detects the AFT voltage of the intermediate frequency IF signal output from the tuner 400 under the control of the microcomputer 200, and provides the detected voltage to the microcomputer 200.

Hereinafter, an automatic tuning method of a broadcast receiver according to the present invention implemented in an automatic tuning apparatus for a general broadcast receiver including a component that performs the above-described function will be described with reference to FIGS. 2 and 3.

2 is a detailed flowchart illustrating an automatic tuning method of a broadcast receiver according to the present invention, and FIG. 3 is a waveform diagram of the AFT voltage detected by the AFT voltage detector 500. FIG. After briefly describing the waveform of the illustrated AFT voltage, the present invention will be described with reference to FIG. 2.

Referring to FIG. 3, a portion indicated by diagonal lines, that is, a predetermined predetermined AFT voltage range is called dead zone, and a portion where a slope of the AFT voltage waveform is negative (-) is narrow AFT (Narrow AFT), The other area is called a wide AFT. In this case, as can be seen from the diagram, when the AFT voltage output from the tuner is a narrow AFT and is located in the dead band, it can be seen that the tuner is tuned to the best state, that is, the center frequency.

Hereinafter, the automatic tuning method of the broadcast receiver according to the present invention will be described taking the case where channel 3 is tuned as an example of the present invention. However, other channels can be easily changed.

In FIG. 2, when a channel key signal is applied from the key input unit 100 (S 10), the microcomputer 200 refers to the PLL data previously stored in the storage unit 300, and the channel key applied from the key input unit 100. PLL data corresponding to the signal is extracted and the extracted PLL data is applied to the tuner unit 400 (S20). That is, when a key signal for channel 3 is applied from the key input unit 100, the microcomputer 200 refers to the PLL data stored in the storage unit 300, and the center frequency corresponding to the channel key signal 61.25MHz. Is applied to the tuner unit 400.

Accordingly, the tuner 400 to which 61.25 MHz is applied receives the frequency signal of channel 3 selected by the user by adjusting the oscillation frequency of the voltage controlled oscillator in the self to 61.25 MHz.

In this case, the AFT voltage detector 500 detects the frequency signal received from the tuner 400, that is, the AFT voltage according to the broadcast signal, and provides the microcomputer 200 with information about the detected AFT voltage. S 30)

In operation S 30, the microcomputer 200 having received information about the AFT voltage from the AFT voltage detector 500 determines whether the AFT voltage detected by the AFT voltage detector 500 is a narrow AFT.

As a result of the determination in step S 40, when the AFT voltage detected by the AFT voltage detector 500 is not a narrow AFT, the microcomputer 200 generates f (n) = f (n−1) − (− for a positive integer n). 1) The center frequency is varied by varying the PLL data according to the formula of ⁿ (0.5n).

That is, since n = 1 at the first variable, f (1) = f (1-1)-(-1) ¹ (0.5 × 1) = f (0) + 0.5MHz, the previous center frequency 61.25MHz The frequency f (1) = 61.75MHz increased by 0.5MHz.

Thereafter, the above-described steps S30 and S40 are repeated, and as a result, if the detected AFT voltage is not the narrow voltage, the second variable is changed again.

Since n = 2 when the second variable, f (2) = f (2-1)-(-1) ² (0.5 × 2) = f (1) -1 MHz, which is reduced by 1 MHz to the previous center frequency of 61.25 MHz. The frequency f (2) = 62.25 MHz is varied. In this case, f (2) is a value reduced by 0.5MHz compared to the center frequency f (0) applied by the first PLL data.

Thereafter, the microcomputer 200 repeats the above-described process until the AFT voltage is detected as a narrow AFT, f (0) = 61.25MHz, f (0) + 0.5MHz = 61.75MHz, f (0) -0.5 MHz = 60.75MHz, f (0) + 1.0MHz = 62.25MHz, f (0) -1.0MHz = 60.25MHz, f (0) + 1.5MHz = 62.75MHz, f (0) -1.5MHz = 59.75MHz .. As described above, the AFT voltage is detected while the center frequency by the PLL data is varied in a unit of 0.5 MHz in a zigzag form around f (0). In this case, the present invention determines whether or not a narrow AFT is added to the PLL data in units of 0.5 MHz, but the addition unit may be easily changed for convenience. (S 50)

As a result of the determination in step S50, when the narrow AFT is detected, the microcomputer 200 determines whether the detected AFT has a voltage range within the dead band (S60).

As a result of the determination in step S 60, when the AFT voltage detected by the AFT voltage detector 500 is not in the dead band, the microcomputer 200 varies the PLL data by using the equation f (n) = f (n-1) + fs. The center frequency tuned to the tuner 400 is varied. At this time, fs may be set to either 62.5 KHz or 31.25 KHz.

That is, in the step S50, the narrow AFT is detected at f (4) = 62.25MHz, and if the set step frequency is 31.25KHz, the microcomputer 200 adds 31.25KHz to f (4) = 62.25MHz and the PLL. The center frequency by data is varied to 62.28125 MHz, and the AFT voltage at that time is detected.

The microcomputer 200 determines whether the AFT voltage detected by the center frequency 62.28125 MHz is a dead band in step S70, and if the detected AFT voltage is not the dead band, the microcomputer 200 described above is detected until the AFT voltage is detected within the dead band range. Repeat step S70.

That is, by adding the stem frequency 31.25KHz to f (4) = 62.25MHz, the center frequency is varied to 62.28125MHz, 62.3125MHz, 62.34375MHz, 62.375MHz, etc. to determine whether the band is dead. 60)

When the AFT voltage is detected as deadband by repetition of step S 60 and step S 70, the microcomputer 200 controls the tuner unit 400 to tune to the center frequency based on the PLL data at that time.

According to the present invention described above, by searching for a large frequency unit up to the range where the actual center frequency is located, and when reaching the range where the actual center frequency is located, it is variable in units of step frequency and automatically tunes the broadcast receiver by searching for the actual center frequency. There is an effect that can reduce the time required for.

Claims (3)

An automatic tuning method of a broadcast receiver for tuning a tuner to a tuner the center frequency of a channel to be tuned using the AFT voltage after detecting an AFT voltage while varying a frequency applied to the tuner. A first step of detecting an AFT voltage by tuning the tuner to a preset center frequency corresponding to the channel to be tuned; Until the AFT voltage is located in a narrow region having a negative slope, the AFT voltage is alternately changed in units of a variable frequency based on the center frequency tuned to the tuner in the first step, and the AFT voltage is varied. Detecting a second step; When the AFT voltage located in the narrow region is detected in the second step, the AFT voltage is varied in a predetermined step frequency unit at a predetermined center frequency that is variable in the second step until an AFT voltage within a predetermined predetermined voltage range is detected. Detecting a third step; And a fifth step of tuning the tuner to a frequency applied to the tuner when the AFT voltage is detected when the AFT voltage is detected in the third step. Auto tuning method. The method of claim 1, wherein the second step is that when n is a positive integer, changing the frequency according to the relation f (n) = f (n-1)-(-1) ⁿ (0.5n). An automatic tuning method of a broadcast receiver characterized by the above-mentioned. 3. The method of claim 1 or 2, wherein the step frequency is any one of 62.5 KHz and 31.25 KHz.