KR100248139B1 - Automatic fine tuning - Google Patents

Abstract

The present invention relates to a broadcasting channel searching method of a VS system receiving apparatus that changes a tuning frequency according to a PWM output step and outputs an AFT voltage corresponding to a difference between a tuning frequency and a broadcasting channel frequency. When the AFT voltage is applied at a voltage between 4.3 V and 1.5 V by one step value, the first step of increasing the PWM step to a second step value smaller than the first step value until an AFT voltage of 1.5 V is applied. Wow; When the PWM step is increased by a predetermined first step value, but the AFT voltage is applied at a voltage of 1.5V, the PWM step is decreased by a third step value smaller than the second step value until an AFT voltage of 2.5V is applied. A second step; When the step of PWM is increased by a predetermined first step value, but the AFT voltage is applied at a voltage of 1.5V or less, the step of reducing the PWM step by the first step value until an AFT voltage between 3.5V and 2.0V is applied. 3 steps. That is, the present invention has an effect of shortening the channel search time by eliminating the skip phenomenon in the channel search of the VS receiver.

Description

How to navigate channel {AUTOMATIC FINE TUNING}

The present invention relates to a VS (Voltage Synthesize) receiver, and more particularly, to a channel discovery method for eliminating skipping during a channel search of a VS receiver.

During channel tuning, in order to tune the tuner to the center frequency of the frequency band to be received among the signals of the various frequency bands, an applied broadcast channel must be searched.

For this purpose, the European tuner adopts the VS method. The VS method refers to a method of searching for a channel by using an output variation amount of PWM (Pulse Width Modulation) according to an AFT (Automatic Fine Tuning) voltage difference used for tuning a tuner.

Therefore, for the channel search in the VS reception method, it is necessary to store a PWM signal corresponding to the center voltage (for example, 2.5V) of the applied AFT voltage. In addition, in order to selectively store the PWM signal, the AFT center voltage must be output, and thus, a selective output change of the PWM signal for outputting the center voltage is required.

That is, if the AFT voltage (the voltage waveform section at this time is called the window range) provided from the tuner is included in the preset window range (for example, 1.5 to 3.5 V), the PWM output is applied when the AFT center voltage is applied. The fine change is performed in predetermined step units.

Next, the center voltage output process for channel discovery of the conventional VS receiver will be described in more detail with reference to some embodiments.

Prior to the description, the voltage levels in the AFT window are classified into three stages: 3.5, 2.5, and 1.5V. The microcomputer's PWM signal is an initial step (the initial step is 29 steps in the low band) according to the voltage level described above. It is assumed that the output is different in three steps of 18 steps in the high band and 14 steps in the UHF band), 2 steps, and 1 step. In addition, the PWM signal is provided to the integrator, and the integrator outputs a predetermined voltage value corresponding to the PWM signal of each different step to the tuner. In the following description, the functional description of the integrator is omitted for convenience.

First, when the microcomputer applies a PWM signal of an initial step, that is, 29 steps of a low band, to the tuner, the tuner mixes a tuning frequency corresponding to the applied PWM signal with a broadcast channel frequency introduced through an external antenna to provide a connection between the two frequencies. Generates a difference, that is, an intermediate frequency IF. This intermediate frequency is amplified to a predetermined AFT voltage via an IF amplifier and then provided to the microcomputer.

The microcomputer selectively determines whether the AFT voltage provided from the tuner is included in an arbitrary voltage value in the AFT window and selectively controls the PWM output.

In detail, if the applied AFT voltage is 3.5V or more, the microcomputer again increases the PWM output in 29-step units, and if the applied AFT voltage is located within the preset window range, that is, 1.5 to 3.5V, The PWM output is increased in 2 step increments until the AFT voltage is output.

In addition, if the applied AFT voltage is 1.5V or less, the microcomputer reduces the PWM output by one step until the 1.5-3.5V AFT voltage is output.

On the other hand, while the applied AFT voltage decreases the PWM output in one-step increments until the center voltage, that is, 2.5V, is output, and when the applied AFT voltage exceeds 2.5V, the PWM value increased by one step is reversed. After checking the presence of the synchronization signal, if there is a synchronization signal, the PWM value is stored, and the operation of increasing the initial step from this position, that is, the stored PWM value, is repeated, and the channel search is started again by finding the initial position, that is, the 4.5V position.

When the center voltage is applied through the above process, the microcomputer determines whether the synchronization signal is present and then stores the PWM signal corresponding to the above-described center voltage.

However, in the conventional channel search method, one problem occurs during channel search.

That is, if the initial applied AFT voltage is slightly greater than 3.5V (for example, 3.51V) at the time of increasing output of PWM, if the PWM signal of 29 steps is output at that position, the AFT section of 1.5V to 3.5V cannot be found and skipped. Occurred.

In addition, when the AFT voltage applied at the reduced output of the PWM is slightly larger than 1.5V (for example, 1.51V), when outputting the PWM signal of 2 steps at the position, the AFT voltage of 1.5V may not be found and skipped. Occurred.

Therefore, the conventional channel search method has a problem that the channel search time is delayed more than necessary.

Accordingly, the present invention has been made to solve the above-described problem, and the channel search method for eliminating the skip phenomenon during the channel search of the VS receiver by setting the AFT window range differently according to the increase / decrease of the PWM output. The purpose is to provide.

In order to achieve the above object, the present invention provides a broadcasting channel searching method of a VS method receiving apparatus that changes a tuning frequency according to an output step of a PWM and outputs an AFT voltage corresponding to a difference between the tuning frequency and a broadcasting channel frequency. If the step of PWM is increased by a predetermined first step value but the AFT voltage is applied at a voltage between 4.3 V and 1.5 V, the PWM is at a second step value smaller than the first step value until an AFT voltage of 1.5 V is applied. A first step of increasing the step; When the PWM step is increased by a predetermined first step value, but the AFT voltage is applied at a voltage of 1.5V, the PWM step is decreased by a third step value smaller than the second step value until an AFT voltage of 2.5V is applied. A second step; When the step of PWM is increased by a predetermined first step value, but the AFT voltage is applied at a voltage of 1.5V or less, the step of reducing the PWM step by the first step value until an AFT voltage between 3.5V and 2.0V is applied. Provided is a broadcast channel discovery method of a VS method receiving apparatus, comprising three steps.

1 is a block diagram of a VS method receiving apparatus performing a channel searching method for eliminating a skip phenomenon according to the present invention;

2 is a flowchart of a channel searching method for eliminating a skip phenomenon during channel searching in a VS method receiving apparatus according to the present invention;

3 is a waveform diagram of the AFT voltage at the PWM increase output of the microcomputer of FIG. 1;

4 is a waveform diagram of an AFT voltage at the PWM reduction output of the microcomputer of FIG. 1.

<Description of the code | symbol about the principal part of drawing>

10: tuner 20: IF amplifier

30: microcomputer 40: integrator

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

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

1 is a block diagram of a VS system receiving apparatus for performing a channel searching method according to the present invention.

As shown, the VS method receiving apparatus includes a tuner 10, an IF amplifier 20, a microcomputer 30, and an integrator 40.

First, the tuner 10 mixes a broadcasting channel frequency introduced through an external antenna and a tuning frequency changed according to a voltage value from the integrator 40 to output a difference, that is, an intermediate frequency, between two frequencies.

The IF amplifier 20 filters and amplifies the intermediate frequency from the tuner 10, demodulates it to a predetermined AFT voltage value, and provides it to the microcomputer 30.

The microcomputer 30 is a means for controlling the overall operation of the VS system receiving apparatus, and as determined from the description below, it is determined whether the AFT voltage provided from the tuner 10 is included in an arbitrary voltage value in the AFT window. To selectively control the PWM output.

In addition, the microcomputer 30 determines whether a synchronization signal is present in the broadcast signal received from the tuner 10 and stores the corresponding PWM signal.

On the other hand, the integrator 40 integrates the PWM signal output from the microcomputer 30 to a predetermined voltage value and provides it to the tuner 10.

Next, the process of outputting the center voltage for channel search of the VS receiver according to the present embodiment together with the above-described configuration unit will be described in detail with reference to the flowchart of FIG. 2.

Prior to the description, it is assumed that the AFT voltages have different window ranges as the PWM output increases or decreases. That is, as shown in Figure 3 is classified into steps of 4.3, 2.5, 1.5V in the PWM increase output mode, and as shown in Figure 4 is classified into steps of 3.5, 2.5, 2.0V in the PWM decrease output mode, respectively. You will see that it is. Accordingly, the PWM signal of the microcomputer 30 outputs different output values of initial steps (29 steps in the low band, 18 steps in the high band and 14 steps in the UHF band) according to the above-described voltage level to output the center voltage, that is, 2.5V. 3 steps of 2 steps and 1 step are output differently.

First, when the microcomputer 30 provides a PWM signal of an initial step, that is, 29 steps, to the integrator 40, the integrator 40 integrates the PWM signal and tunes the predetermined voltage value corresponding to the applied PWM signal. (Step 100).

In the tuner 10, a tuning frequency corresponding to an applied voltage value and a broadcasting channel frequency introduced through an external antenna are mixed to generate a difference, that is, an intermediate frequency IF. This intermediate frequency is amplified to a predetermined AFT voltage via an IF amplifier and then provided to the microcomputer 30 (step 102).

The microcomputer 30 determines whether the AFT voltage provided from the tuner 10 is included in an arbitrary voltage value in the AFT window and selectively controls the PWM output.

In detail, if the applied AFT voltage is 4.3V or more (step 104), the microcomputer 30 again increases the PWM output in units of 29 steps (step 100), and the applied AFT voltage is between 1.5 and 4.3V. Once positioned (step 106), the PWM output is increased in two step increments until a 1.5V AFT voltage is output (step 108).

If the applied AFT voltage is 1.5V (step 110), the microcomputer 30 decreases the PWM output by one step until the 2.5V AFT voltage is applied (step 112, step 114).

At this time, if the applied AFT voltage exceeds 2.5V, the microcomputer 30 increases the PWM at the current position and reaches the initial position, that is, the 4.3V position, to continue the channel search (step 116).

In addition, if the applied AFT voltage is 1.5V or less (step 118), the microcomputer 30 decreases the PWM output in initial step units until an AFT voltage of 2.0V to 3.5V is applied (steps 120 and 122). .

On the other hand, when the center voltage of 2.5V is applied to the microcomputer 30 (step 114), the microcomputer 30 determines the presence or absence of a synchronization signal (step 124). If a synchronization signal is detected, the microcomputer 30 stores a PWM signal corresponding to the center voltage (step 126). If the synchronization signal is not detected, the microcomputer 30 searches for a channel at an initial position, that is, a 4.3V position. Start (step 100).

As described above, the present invention has the effect of shortening the channel search time by eliminating the skip phenomenon in the channel search of the VS type receiving apparatus.

Claims (5)

A broadcasting channel searching method of a VS method receiving apparatus which changes a tuning frequency according to an output step of a PWM and outputs an AFT voltage corresponding to a difference between the tuning frequency and a broadcasting channel frequency. When the step of the PWM is increased by a predetermined first step value, and the AFT voltage is applied at a voltage between 4.3 V and 1.5 V, a second smaller than the first step value until the AFT voltage of 1.5 V is applied. Increasing the PWM step by a step value; When the step of the PWM is increased by a predetermined first step value, and the AFT voltage is applied at a voltage of 1.5V, the stepped third step value is smaller than the second step value until the AFT voltage of 2.5V is applied. A second step of reducing the PWM step; If the step of the PWM is increased by a predetermined first step value, and the AFT voltage is applied at a voltage of 1.5V or less, the PWM is applied to the first step value until the AFT voltage between 3.5V and 2.0V is applied. And a third step of reducing the steps. The method of claim 1, further comprising detecting a synchronization signal after performing the first, second, and third steps. The method of claim 1, wherein the first step is an initial step. The method of claim 1, wherein the second step is two steps. The method of claim 1, wherein the third step is one step.

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